DE868931C - Circuit arrangement for establishing connections in telecommunications systems - Google Patents

Description

The patent 853 302 relates to a circuit arrangement for making connections in Telecommunication systems in which a group of subscriber lines is jointly assigned call-terminating device means contains which respond simultaneously to information relating to the identity of a plurality of calling subscriber lines, and furthermore has a plurality of non-numerical connection devices which are set up in this way are that each of the simultaneous calling lines due to the control of the call screening equipment is switched through in sequence.

The invention shows as a development of the patent 853 302 a circuit device for Establishing connections in automatic telecommunications systems. It consists in the individual Selector stages memory control devices are assigned, the switching elements of which respond to control signals of each selector stage address and, depending on the signals received, enable the following choice or in modify another switching process.

The advantage of the invention is to be seen in the fact that the memory control device takes up distinctions, whether, for example, a calling subscriber is authorized to set up a certain connection or whether a hunt group of a line selector is set. In the first case, the further connection establishment is prevented, in the second case a free line connection is selected causes, it should also be noted that the

'Lines of the hunt group can be arranged scattered in the contact field.

Fig. Ι shows the subscriber part of the exchange circuit;

Fig. 2 shows a call screening circuit common to a plurality of subscriber lines and also a multiple dialer for connecting the call screening circuits to the connection sets;
3, 4 and 5 show the common control circuit to control the operation of the multiple dialer belonging to the call setting circuit;

Fig. 6 shows a call search circuit which contains the single dialers of a multiple dialer, its Operation is described below;

Figures 7 and 8 show the common control circuit used to control the operation of the call seekers and to control the line selector; 9 and 10 show a connection kit such as he is between the call search and the dialing means;

Fig. 11 shows the common control circuit that

controls the functioning of a multiple voter provided is to establish the connection between the storage controller and the connection set accomplish;

Figs. 12, 13, 14. and d.15 show the memory control circuit;

Fig. 16 shows the internal circuit of a single group selector;

Figs. 17 and 18 show the common control circuit for. the group voter;

Fig. 19 shows the internal circuit of a line 35. Voter using the same common control circuit as the call seeker, i. H. those in Figs. 7 and 8 shown;

FIG. 20 shows how the circuit diagrams in FIGS. 1 to 19 must be placed against each other in order to produce the complete exchange circuit;

Fig. 21 shows the timing diagram of the time-defined Pulses used to control election;

Fig. 22 shows a table indicating how the pulses of Fig. 21 are used to make the selection to control.

The system is set up in such a way that the line selector depends on similar components work; therefore, the first call seekers and the line selectors share the same one Control circuit.

The call seekers and line selectors have one

Capacity of 100 lines each, and the subscriber circuits of the office are accordingly divided into groups of hundreds. Those subscriber lines whose numbers are only in distinguish between tens and units therefore to the same group of call seekers and line voters who together make up the voters of one for 100 lines provided multiple selector.

The subscriber lines are through the connection sets associated call terminator operated.

A certain number of these connection set finders together form a multiple selector and has access to a group of connection records that are parallel to said multiple selector.

The number of connection set seekers, each of which is related to a caller and which together form a multiple selector is determined by traffic requirements.

A certain number of storage control devices is allocated to the connection sets by means of a multiple selector RS (FIG. 20)! A common control circuit is provided for a group of memory control devices that use the same multiple selector. If a connection set is selected by a call detection circuit, it is possible to ensure that the selected connection set also has access to a free memory, - by continuing the test circuit of each connection set to the associated memory control devices via the common control circuit or circuits that the control memory circuits belonging to one another with the connection set.

All dialing and retiring processes used in control and internal connections are controlled by electrical impulses that are timed in a certain way within Pulse cycles lie. These impulses change in their duration depending on the process to be carried out, but they all come from different sources for electrical pulse cycles. The relationship between said cycles is such that each pulse has a second cycle of a duration equal to the total duration of a full first cycle during each pulse of a third Cycle has a duration equal to the total length of the second cycle, and so on. By doing combinations of pulses belonging to a different number of such sources are used, there is a resulting pulse cycle, which consists of the pulses of the first cycle, said resulting cycle has a number of pulses which is equal to the product of the ZaId of is pulses contained in each of the individual cycles; for example, cycles of six make five and four pulses together make a cycle of 120 pulses.

Fig. 21 shows the timing diagram of the various Sources generated pulses, said pulses being used as a time base, to form a code of 1200 elements.

Two main groups of pulse sources are provided; the first are denoted by Pa, Pb, etc., while the others are denoted by Ra, Rb, etc.; the main difference between these two groups of pulse sources lies in their potential difference. The P sources are always intended for use in the grid circle of an amplifier tube and their potentials are dimensioned accordingly. On the other hand, the i? Sources are always intended for use on the control electrode of cold cathode tubes and their

Potentials have been adapted to the operating conditions of the said facilities.

Each of the groups Pa and Ra consists of six sources, each delivering a pulse during six successive time segments of a periodic cycle. The duration of each of these impulses corresponds to the duration of the elementary segment (unit of time) on which the whole system is based; in the following it is to be taken as a unit of time.

ίο Each of the groups Pb and Rb consists of five sources that each deliver an impulse in five successive time segments that form a periodic cycle. The duration of each of these pulses corresponds to six time units from the sources Pa and Ra and their period thus corresponds to 30 time units from the sources mentioned.

Each of the two groups Pc and Rc contains four sources of time-defined pulses, the length and period of which correspond to 30 or 120 time units of the sources Pa and Ra.

The group Pd contains ten sources whose pulses correspond to 120 time units of the sources Pa and Ra and whose period corresponds to 1200 time units. These ten sources, like those of the other groups, generate temporally defined pulses which are offset from one another in such a way that the pulse generated by each of these sources follows that of the previous source.

Five sources Rd are provided, which are identical to the sources Pd ι ... Pd 5 with regard to their temporal properties.

Fig. 21 also shows the timing relationship between the source Pa and the three declaratory sources dl, the parking sources dz and d 3, dl and d2 transmitted pulses that also lie within the associated pulse Pa, when said pulse is shortened. The detection source d $, which corresponds to d 2, transmits a pulse at the beginning of the next transmission period of the basic source Pa. The sources of the first three types, Pa, Pb and Pc, are used to control the transmission of a signal made up of timed pulses and the detection of a signal produced in the same way. The simultaneous use of any three sources of different types enables 6X5X4 = 120 different time-defined signals to be formed. On the output side, these 120 time signals are used to scan 100 voter connections and 20 additional information that can be temporarily assigned to said connections in any desired manner. In order to enable searching of the 100 voter connections, said connections have been distributed over the 120 connections in such a way that only the first five units in each of the successive groups 1 ... 6, 7 ... 12 are used for searching connections during the last time unit is not used for this purpose. In other words, the sources Pa 1 ... Pa 5, which emit periodic pulses, are used to search the 100 voter connections, while the periodic pulse source Pa 6 is not used. The source Pa 6 is therefore used in sequence to study the 20 remaining electrical states during the 20 pulses coming from said source within a period of 120 time units.

On the receiving side, the pulses are received after they have been shifted by a time unit in that the sources dz and d 3 are used one after the other for the transmission and reception of the pulses, so that a pulse which emanates in time segment no No. 2 arrives, etc .; consequently, the pulses transmitted in the first five time segments of each group are recorded in the last five time segments of each of said groups. The sources Ra 2 ... Ra 6 are thus used when the pulses arrive which characterize the 100 selector connections and are transmitted by means of the sources Pa ι ... Pa 5. The pulse source Ra ι is used exclusively if the 20 above-mentioned special information, which is transmitted by means of the source Pa6 , come to an end.

The sources Pd 1 ... Pd 10 are used to associate a special group information with each of the connections and so, for example, in the case of connections to a group selector, to use these sources to identify the group of the respective connections.

Fig.22 shows how the transmission sources Pa .. .Pc are used together with three stages of electric valves to give impulses to the storage control devices. The table shows which sources have to be used for the valves belonging to each connection. This table also shows the time interval in which a pulse must be sent for each of the connections.

The call searcher circuits, group dialer circuits and line dialer circuits are intended for use in a multiple selector that has the following properties:

The multiple selector contains a certain number of horizontal voting sticks, each of which as The counterpart of a single voter can be viewed as having a connection in the manner of a self only in one direction moving voter of well known type.

100 connections are provided for all individual voters accessible and common to them.

If a horizontal and a vertical selector rod have been operated one after the other, a certain number of contacts located at the intersection of these rods is closed, as a result of which the individual selector is connected to the relevant connection via said contacts. For example, in the selector shown in FIG. 6, these contacts are five in number and denoted by the letters A, B, C, D and E. To the left of these contacts, the connection line is drawn, which end in the iao selector connections that can be reached via the relevant vertical selector rod; to the right of these contacts, the circuit parts belonging to the individual selector are drawn. The 100 connections are divided into two groups of 50, with 50 coordinate points between each horizontal and vertical bars

-the two. Sentences to five contacts sit. Each • vertical rod is assigned its own working magnet, which pushes the selector rod upwards in the event of excitation. A horizontal voting stick is provided for each of the χ individual voters that make up the Mehrfachwäliler.;, A separate horizontal magnet is provided for each voter and two horizontal auxiliary magnets that are common to all voters. The response of a ^ single horizontal magnet does not yet actuate the associated horizontal selector rod, but only the response of a horizontal magnet and then one of the horizontal auxiliary magnets pushes the corresponding horizontal rod to the left or right in order to move one or the other set of contacts to the other coordinate intersection close, which is determined by the shifted vertical and horizontal bars. Similar precautions are taken for the group selector (Fig. 16) and line selector (Fig. 19); it should only be noted that the circuit parts ending in the selector connections here to the right of the contacts A, B, C, D and E are drawn in, while the circuit parts that belong to the individual selectors are drawn to the left of said contacts.

The call finder, the group dialer and the line dialer are, as already stated, dialers - with 100 positions that use horizontal auxiliary magnets - to choose between two sets of 50 connections; the multiple voters. CCS (Fig. 2) and RS (Fig. 12), which exist between the call detection circuits and ^; Connection sets on the one hand and the memory control devices and connection sets on the other hand do not need such a large one. Number of connection options. There are therefore no horizontal auxiliary magnets in these small multiple selectors; the individual horizontal magnets directly control the horizontal selector rods themselves.

A 100 subscriber lines shared call operator can simultaneously use a call (pick up) on any number of these lines regenerate resulting impulses, so that an impulse is regenerated, which in each case the identity identifies each of the calling lines.

If two or more lines call (pick up) at the same time, the call terminator seizes one free connection set and a free memory circuit via the associated common control circuit and causes you to be connected to one of the calling lines, whereupon he again has a free one .Connection record and another free memory are occupied and assigned to the next calling line and so on. The calling lines are served in the order in which they are in no particular order : arrive the impulses that mark the identity of each line; the line whose impulse is after their connection to a memory first reaches the common control circuit of the caller, is the first to be connected. ... The common 'control circuit that one certain number of with a group of connection sets linked caller conditioner circuits in common, can be done with the help of electron tubes the search for one for any number of call arresters operated by you at the same time initiate a free connection set.

If we assume that in a group two or more call terminators are looking for one at the same time If you are looking for a free connection set, the shared connection set will be shared after a connection set has been found Control circuit to this one of the calling call terminators. This allocation of free connection sets to the call termination circuits takes place without a fixed sequence and by means of electron tubes instead of.

As soon as one of the call detectors in the just described Way has been connected to a free connection set, seeks the common Control circuit according to a further free connection set for another caller waiting.

As long as the subscriber loop is interrupted, the negative end of a 48-V battery is on the one hand on wire B (Fig. 1) via a 30,000 ohm resistor and on the other hand on the C wire via said 30,000 ohm resistor and still another 30,000 ohm resistor in series. The C-wire is also connected to three rectifier cells, the other end of which is at such a potential that these rectifier tents are non-conductive as long as the line is idle, so that no current flows through this rectifier group to the call operator.

If the line loop is closed when lifting the handset, current flows in the following Circuit: earth, resistance, 15000 ohms, vi wire, subscriber loop, .B wire, 30,000 ohms, Battery. The potential of the ΰ-wire comes to about - ■ 16 V. The exact level of the potential on the .B wire depends on the resistance of the subscriber loop away.

This potential of the B-wire makes it possible that current can flow from the B-wire to the grid of the tube VAD 1 (Fig. 2) via the parallel cells connected in series with the Q-wire. Said grid circuit is brought to -40 V by the voltage divider DPT, so that the rectifiers in question are then conductive Rectifier cells that are connected on the one hand to the wire that ends in the call terminator (Fig. 2) and on the other hand are connected to the power sources Pa ι ... Pa 5, Pb 1 ... Pb 5, Pc 1 ... Pc4.

These sources are usually at - 40 V, but this potential can be at certain times can be raised to -16V. Electricity can only flow and sustain after the call arrester when said sources are all brought to -16 V; if on the other hand even if only one of the sources is at -40 V, then this is the last potential that in the end has the

Rectifier cells on the wire Q , arrives, which ends in the call determiner; Therefore this cell, which is at -40 V, does not allow any current to pass through to the call terminator, and the potential difference between the D wire and the Q wire ending in the call terminator is swallowed up in the 30,000 ohm resistor on the 5 wire. The arrangement of the rectifier cells described here acts as a valve through which the current flowing on the Q wire ending in the call terminator can be suppressed.

The first rectifier system belongs to the relevant line and is connected to one of the five sources Pai .. .Pa 5. These sources are at -16 volts at a different point in time during one of the five consecutive time periods of each source, so the pulses of each source are reproduced with five time periods in between when the source is at -40 volts.

The period of the pulses of each source corresponds to six time segments by bringing source Pa 1 in time segment No. i, source Pa2 in time segment No. 2 to -16 V, and so on, until finally source Pa 5 in time segment No. 5 of a group of six Periods of time is brought to -16 volts. In the sixth time segment of each recurring period none of the sources Pa / ... Pas is at -16 V, but a sixth source Pa 6, which is not shown in this circuit.

The 100 lines of a group are divided into 20 subgroups of five lines; in each group of five lines, the rectifier assemblies are repeatedly connected in the same way to the various sources Pa , ie that of the first line of each group with source Pa 1, that of the second line with source Pa 2 , etc. and that of the fifth line of each group with source Pa 5.

The five lines of each group are above one

first rectifier system peculiar to each line on a second in series with it Rectifier system, the latter rectifier system each having a group of five lines What is common is that 20 rectifier systems like the one mentioned above are provided for 100 lines.

These 20 rectifier systems are again divided into four groups of five. In each group of five, the rectifier systems are connected to one of the sources Pb 1 ... Ph 5, i.e. the first of each group with source Pb 1, the second of each group with source P & 2, etc. and the fifth of each group with source Pb 5.

The sources Pb 1 ... Pb 5 are brought to -16 V in one of five successive time segments, each of these time segments corresponding to six time segments of the sources Pa and coinciding with one of the cycles Pa 1 ... Pa 6. This happens for each source at a different point in time, i.e. for source Pb 1 during time segments 1 ... 6, for source Pb 2 during time segments 7 ... 12 etc. and for source Pb 5 during time segments 25 ... 30. During the time segments between the pulses of each source, which correspond to 24 time segments, the potential sources are at -40 V, and it can easily be seen that the repetition period of the pulses from the potential sources Pb is 30 time units.

Each of the second groups of rectifier systems is connected to a common point, which in turn is connected to a third system of rectifiers. Said system of Rectifiers is one of the four preceding groups; H. common to a group of 25 lines.

There are thus four rectifier systems like the one above, each of which is connected to one of the four sources Pci .. .Pc 4.

The sources Pci ... Pc 4 are each brought to -16 V in a different time segment of four successive time segments; Each of these time segments corresponds to 30 time units and falls on one of the cycles of the sources Pb 1 ... Pb ^ ₁ , ie for source Pci on the time interval ι ... 30, for source Pc 2 with the time interval 31 ... 60, for Source Pc 3 with the time interval 61 ... 90, for source Pc 4 with the time interval 91 ... 120. Each of the sources is at -40 V for a period of 90 time units. The frequency of occurrence of the pulses from Pc sources corresponds to 120 time units. The four rectifier systems just described are connected to the call detection circuit via a single wire Q.

The operation of the system will now be described. If a line calls (picks up), so the wire Q, which ends in the call terminator, remains at -40 V except at a point in time that is indicative of the identity of the calling line concerned; at this point the potential of the Q wire ending in the call terminator is around -16 V. During this period of time are all branching rectifiers related to the calling line non-conductive, because the potential sources connected to them are all at -16 V. this happens for each of the 100 lines forming the relevant group at a different point in time, so that by determining the point in time at which the -16 V pulse is transferred to the call operator no averages, the identity of the calling line is established.

As explained above, a call (pick-up) is placed on one of the lines of the Group identified by an impulse on the common Q wire that lines the ioo subscriber lines connects to the call operator, with this pulse once every 120 time units repeats and enables the tens and ones digits of the caller's number to be identified.

These pulses are transmitted to the grids of two amplifier tubes VADi and VAD 2 in the call termination circuit (FIG. 2). The grids of the two amplifier tubes are normally at -40 V from a voltage divider DOT, which is made from

, two 'resistors of 600 kOhm and 120 kOhm. "Each of these amplifier tubes !! /, which together form a double triode, controls a pulse regeneration tube VAD3 / VAD4, whereby these S tubes also form a double triode.

-The first of these pulse regenerators VAD 3 is used to energize relay DT every time a line calls. This relay prepares all further switching processes that are necessary to connect a free connection set and a free memory circuit to the calling line. Relay DT is also used as a line relay for a group of 100 lines served by a call operator. The second pulse regenerator VAD 4 transmits a fresh pulse for each incoming pulse from the calling line, which is slightly shorter than the original pulse and slightly delayed compared to the actual time of the original pulse. These pulses are used by a call finder to locate the calling line, as described below. '

"A pulse from a calling line via the common Q-wire goes directly to the left amplifier tube VADi, the grid of which is normally so strongly biased that the tube blocks as long as no pulses arrive. The grid of the left regenerator tube VAD 3 is also so strongly biased that no current flows through one or the other of the two windings of the transformer DTT or through said tube. The pulse brings the grid of the amplifier tube VADi to a more positive potential; a current then flows in the anode circuit and the potential of the anode becomes more negative because of the resistance ratios This change in potential is transmitted to the anode of the regeneration tube VAD 3 and thus causes a current to flow in the primary winding of the transformer DTT. Current then flows in the secondary winding of said transformer DTT and the grid the regenerator tube has an even more positive potential r the potential difference is large enough to cancel the winding of the grid bias, the generator is triggered. Anode current begins to flow through the anode winding of the transformer DTT , making the grid more positive; this process continues to rock and the anode current continues to increase. So almost immediately the grid potential is raised above the cathode potential; a relatively strong grid current flows, which prevents the grid voltage from increasing further. At this moment the anode and grid currents begin to decrease, the latter more rapidly than the former, so that the difference in the number of ampere turns of the windings of the transformer in the grid circuit or anode circuit increases even more.

After a certain time, the duration of which is high. Dimensions of the self-induction of the transformer windings and the internal resistance of the tube depends, the grid current becomes zero again. From -. From this moment on, every further decrease in the anode current caused by induction causes a decrease of the grid potential, which in turn causes a further reduction in the anode current. The tube is thus quickly blocked and remains in a stable state until another one Trigger pulse is received.

In this way a rectangular pulse is generated, the amplitude and duration of which are neither of the amplitude still depends on the shape of the triggering impulse.

The type of transformer used and the values of the other circuit elements are such that, according to the method described, a pulse of about 10 ms duration is applied to the winding of the relay DT , which is connected in series with the anode winding.

With a time base that delivers 5000 pulses / sec, the pulses caused by the calling line occur again every 24 ms corresponding to 120 time units. Relay DT remains energized for every 24 ms period due to the discharge of the 4 microfarad capacitor DTC, which is charged during every 10 ms pulse; Relay DT therefore remains energized as long as pulses are received from the calling line, provided that its response circuit is otherwise closed.

The impulses arriving via the Q-wire from each calling line are not transmitted directly to the grid of the right amplifier tube VAD 2 , but are sent via a resistor of 300 kOhm. This grid is connected through a small capacitor IMC to a point CDP which is common to a group of call operators; said common point is connected via two rectifier cells CDRCi, CDRC 2 to a voltage divider CDT in such a way that said common point cannot become either more negative than -40 V or more positive than -24 V; its potential is a source of d 1 is determined, which is connected to the common point via a resistor of 10 kOhm, whereas their 21 is shown in timing diagram FIG.. Usually this source is relatively negative and provides short, relatively positive pulses towards the end of each pulse Pa. The voltage divider prevents the potential changes which arise as a result of the connection of this pulse source to the grid of the amplifier tube VADa via the capacitor IMC from becoming greater than 16 V in their amplitude; under these circumstances the intensifier tube remains blocked. This is due to the fact that normally the grid opposite the cathode is about -20 V, since the potential of the cathode is kept at about -20 V by the action of the suppressor tube SVΆ 4 (FIG. 7); the suppressor tube is located in the common control circuit of the call seeker and line selector and is connected via wire I that can be seen in both FIG. 2 and FIG. ,

Let us now consider a period of time when an impulse arrives from a calling line loop; At the beginning of this period of time, source d 1 is at -40 V, and the pulse, which is positive compared to -40 V, charges the capacitor IMC more and more via the 300 kOhm resistor, so that the grid potential is approximately -32 V. It goes without saying that in this way the amplifier tube VAD 2 still remains blocked.

As the grid comes to -32 volts, source d 1 is transmitting a relatively positive pulse with an amplitude of -16 volts; therefore the grid of the amplifier tube comes up - ιό V. Because the cathode is at - 20 V, the coincidence of the effects produced on the one hand by the pulse transmitted by source di causes the unblocking of the tube FAD 2, while these pulses would not be able to do so individually to produce such a result.

This allows the right- hand regenerator tube VAD 4 to respond using a method which is identical to that already described for the left-hand regenerator tube VADs . The type of transformer used and the values of the other circuit elements are dimensioned so that the duration of the pulses transmitted in this case corresponds to about half a time unit of the basic sources Pa and Ra, ie 0.1 ms. When the call pulse and the coincidence pulse transmitted by the source di cease, the capacitor IMC discharges more and more; when the next pulse from source d 1 is transmitted, the capacitor is discharged so that the pulse transmitted by source d 1 cannot trigger the amplifier stage provided that a call has not occurred on the line represented by the next time period. If the latter case occurs, the capacitor IMC will not discharge as a result of the arrival of a further call pulse, and the amplifier and regeneration stage would be triggered again by the positive pulse from di. This means that a pulse is transmitted for each calling line.

The cathode resistance of the regenerator tube VAD 4 converts the current pulses into voltage pulses, and the presence of the varistor VS in the cathode circuit keeps the potential of this pulse essentially constant over the entire duration of the pulse.

The impulses of the regenerator tube can be picked up either on the cathode or on the grid circle which practically results in pulses of the same amplitude as in the cathode circle.

The impulses taken from the cathode circuit are now used to transmit the identity of the calling line to the common control circuit of the call seeker and line selector (Fig. J) via wire III; the common control circuit uses this information to control the call seeker in the memory circuit. in the manner described below to search for the calling line.

The pulses picked up at the grid circle are transmitted via wire II of the common control circuit of the call seeker and line selector (Fig. 7), where they act on the suppressor tube SVA 4 , so that the pulse generator SVA1 / SVA2 in the common control circuit to select the desired line is used by a line selector, cannot respond and therefore cannot seize the line as long as it calls itself. Therefore, a line can no longer be seized by line dialers from the moment the subscriber answers; outgoing calls have priority in every respect.

A call terminator who finds a calling line can use a common control circuit at any time (Fig. 3, 4, 5) serving a group of callers independently whether one or more call terminators are already using the common control circuit.

The connection of the common control circuit is done by the response of relay DT, which applies earth to the response circuit of relay DES in the common control circuit via the closed normally open contact Λ3, normally closed contact 3 ,, normally closed contact dek ^. (Fig. 3).

Relay DT also places a ground connection via the normally open contact dt 1 and normally closed contact DHB ι to the common control circuit, but initially without any effect.

The attraction of relay DES (Fig. 3) energizes relay DEB via the normally open contact desi, normally closed contact defi2, normally closed contact dec 4 and causes a free connection set to be selected by the common control circuit.

Free connection sets are identified by the earth potential on the test wire F , which is connected to one of the connection points numbered from 00 to 24 in the common control circuit of the caller ID via the following path: earth in the memory circuit, break contact 1 & 4 (Fig. 13), ιo-kOhm -Resistance in the common control circuit of the memory (Fig. 11), RSF wire, normally closed contact rsh 6, normally open contact rsb 4 of relay RSB in the common control circuit of the memory, said relay normally being energized in an easily traced circuit, via normally closed contact ccbcg in the connection set (Fig. 10), F-Adev (Fig. 2) and the connection point in the common control circuit of the caller who corresponds to the connection set.

The connection points numbered 00 to 24 correspond to the outgoing number of the connection set seeker CCS which belongs to the call termination circuit. The number 25 is chosen arbitrarily, but in practice it depends on the traffic data.

The earth applied to one of the connection points 00 to 24 indicates a free connection set; it is provided in order to shift the grid potential of the triode DEV 2 , which is normally reduced to -40 V by the voltage divider DEPT 1

86a

is held! Said voltage divider consists of resistors of 240 kΩ and 1200 kΩ and is connected to the grid via a further resistor of 200 kΩ .

As a result of the insertion of three stages of rectifier systems between each of the connection points 00 to 24 and the grid, an earth connection applied to any of these points can only influence the grid potential during the corresponding point in time _: among the 120 time segments, - because to which - rectifier systems pulse sources are connected, as already described; »-. . ~. -. . . . _: . -

A group of 25 connections of this type can be individually differentiated by 30 time units der-source Pe, said 30 time units

-. correspond to a time unit of the source Pc; accordingly, a single source Pci is used for the third level of equilibrium cells. The transmission of "ines impulses" depending on the source Pc 1 can be prevented by placing a second source Pc2 -the first in parallel in such a way that one of the two sources Pc is always at -40V.

When the circuit is in retirement, i.e. when relay DES has dropped out, a relay DEGB is excited via, the normally closed contact of 7, and an auxiliary rectifier connected to source Pc 2 is then placed in parallel with the corresponding rectifier of source Pci. It can be seen that, as long as the circuit is free, the rectifier normally used and connected to source Pc 1 is short-circuited via the normally closed contact of 3 and normally open contact degb i, through the auxiliary rectifier connected to source Pc2, so that the potential at the- common wire of the connection points 00 to 24 is therefore kept at -40 V at all times; but if one puts another parallel to a source Pc 1 , all the pulses corresponding to the 25 time units are suppressed so that the grid potential is not applied by any end connections lying the free connections is affected as long as the circuit is free.

When energized, the relay DES opens the shunt circuit with its normally closed contact of the 3.As a result, the first connection point, which can report a free voltage generator due to the presence of earth on its P-wire, causes the transmission of a positive pulse to the grid circuit of the amplifier tube DEV2 in the Period of time which is characteristic of said switching.

The grid circle of the tube DEV2 is controlled by a pulse source d 3, the timing diagram of which is shown in FIG.

This source ensures the transmission of a positive

■ - tive impulse at the beginning of each impulse of the elementary source; he can use the amplifier tube and the The associated regenerator tube is only released when the 100 microfarad capacitor is over the the. Source is connected to the grid, while-

■. rend, of the previous period through a. Impulse has been downloaded from a free connection. It can be assumed that in spite of the fact that the pulse has already ended at the point in time at which d - $ - 6g transmits a positive pulse, the capacitor is essentially discharged at this point in time, so that the one in the previous time segment is on the -capacitor -from the connection and the charge coming from the source at the beginning of the next period of time still add up to each other.

The pulse regenerator, which consists of the triode DEVi and a transformer DET , now produces a pulse according to a method which is identical to that already described in connection with the tube VAD 3 (FIG. 2). This pulse begins at the beginning of the pulse transmitted by d 3 or shortly afterwards -and- has an approximate duration of 150 ms, so that it coincides with most of the time segment that follows the one where the Connection sends an impulse. :

The pulse is picked up at the cathode of the regenerator tube DEVi and a group of 16 cold cathode tubes DEVA1 . -. . DEVA 6, DEVB 1 ... DEVBs, DEVCi ... DEVC 4 and DEVD . In each of the three groups mentioned, one tube and the DEVD tube ignite. The DEVA ... DEVC tubes ignite in a combination that indicates that a free connection has been found (Fig. 4). With only 25 connection sets, DEVC tubes are not necessary, but they would be if the number of connection sets were larger. When ignited, the DEVD tube shifts its cathode potential, which is otherwise - 150 V, because it is connected in series to the negative pole of a 150 V battery via the winding of the DEF relay and a resistor. This potential is fixed at -75 V and is transmitted via the rectifier cell DERD to a point on a voltage divider DEPT 3, which is normally at -142 V. This voltage divider has its ends on the one hand at the negative pole of the 150 V battery and on the other hand at the positive pole of a 50 V battery; Another point of the voltage divider, which is connected to the grid of the suppressor tube DEV 3, is normally at a potential in the vicinity of -21.5 V. A second adjustable voltage divider DEPT 4 connects a negative 20 V potential via another rectifier cell DERV with this grid and thus prevents said grid from becoming even more negative.

As long as the grid of the suppressor tube DEV, $ is kept at -21.5 V, its cathode is approximately at the same potential. This potential is also transmitted through the normally open contact deb4 to the cathode of the amplifier tube DEV 2 , which can therefore respond to the pulses transmitted by the valve group on its grid.

When the cold cathode tube DEVD ignites, the potential of the point of the voltage divider DEPT 3 is increased from originally -42 V to -75 V.

As a result, the potential of the point of the voltage divider that is on the grid shifts

the suppressor tube DEV 3, to the effect that

'that it is raised to about ο V; therefore the cathode of this tube is at about the same potential.

Furthermore, the potential of the cathode of the amplifier tube DEV 2 is also brought to ο V, which makes it strongly positive compared to its grid potential; consequently no impulse can pass through the tube

. DEV2 in the following time slots to indicate free connection records. This also applies to every pulse that could arrive in a time segment that immediately follows the one that corresponds to the first set of connections tested, because the DEVD tube ignites at this moment sufficiently soon before the next pulse d 3 to affect the amplifier tube impede.

In the circuits described, the selectors of the call terminator CCS give access to the connection sets which are simultaneously connected to the storage control devices via the selector RS in .dem memory control device (FIG. 12).

It would also be possible that the dialers of the call terminators would allow direct access to the memory control device, which, as already described, would be brought into connection with the connection sets via dialer RS. As already stated, a call detection circuit is only switched on to a connection set when an associated memory control device is free. In this latter case, a call detection circuit is connected to a memory control device only if said memory circuit is related to a free connection set. As soon as a free connection set has been determined by igniting a combination of DEVA ... DEVC tubes, the vertical selector stick corresponding to the connection point of the CCS selector is actuated.
This is achieved by the response of the anode relays DEAA ... DEAF, DEBA. .. DEBE, DECA ... DECD in series with the tubes connected to earth via the normally open contact deb2. These relays have a certain number of normally open contacts which actuate one of the 25 vertical magnets CCSVM of the selector CCS . The magnet CCSVM is held when it is attracted by its own normally open contact ccsvmi, normally open contact dec 6 and earth.

During the operations described above, the common control circuit that the Storage group served to which -the tested connection set has access to the connection on the one hand a free memory circuit to prepare said connection set and to on the other hand this group of stores and at the same time all free connection sets that have access to them have to make temporarily unreachable and thus other common control circuits of the call terminator from checking any of these free connection sets in the period after the connection set has been checked and before it occupies and holds a memory circuit.

The common memory control circuit is occupied when the impulse which excites the combination of tubes and relays in the common control circuit of the call terminator (Fig. 4) also reaches the common control circuit of the memory (Fig. 11) which serves the memory group to which the selected connection set has access.

The pulse transmitted by the pulse regenerator is transmitted to point X , which lies between two resistance coils of a voltage divider made up of three resistance coils DEPT 5 (Fig. 5j; this point is normally at -no V. Point, which is also between two resistors of the said voltage divider; this point Y is normally at - 50 V. When the pulse regenerator transmits a pulse, the potential of point X is raised to - 50 V; this has the effect that the The potential of point Y and circuit CRC is temporarily increased to -17.5 V.

If the call detection circuit and memory circuit are connected to the connection set in the same way, the wire connected to point Y of voltage divider DEPT5 (Fig. 5) is connected directly to point Z of voltage divider RSPT (Fig. 11). This is the case for offices with low occupancy. If, however, the call termination circuits and memories are connected to the connection set according to the various groupings, as can occur in larger offices, it is necessary to mutually connect the points Y of the call termination circuits with the points Z of the common control circuits of the memories in order to achieve such a connection To enable differentiation.

The comparator circuit CRC (FIG. 5) and the concentrating circuit RSCN (FIG. 11) will now be described in order to explain how such arrangements can optionally be carried out. The comparator circuit CRC shown consists of three comparison stages. The wire emanating from point Y is connected to a comparison device; each such device is in turn connected to five comparison devices, which in turn are connected to five other comparison devices. It is thus possible, for example, to satisfy the requirements of a 10,000 office. Of course, you can also use a smaller number of comparison levels.

The comparator circuit distributes the pulses that can arrive in sequence at point Y at the ends of the comparator CRC , one for each end of the wires OZ. These wires are connected through with the points / Z (Fig. 11) in the corresponding concentrating circuits RSCN in the common control circuit of the memory, each containing a rectifier cell per wire in each stage in order to exclude mutual interference between the different wires. The circuit shows, for example, 25 wires at the outlet

output of the comparator device, these being connected via a first stage of five wires, which in turn are connected to point Z of the voltage divider RSPT . Such comparators and concentrators are described in the invention filed by the proprietor of the patent on June 2, 1949, “System for the cyclical search of electrical lines or devices and for the comparison of electrical states”.

These systems of rectifier cells are connected in such a way that the impulses of 17.5 V only reach that connection point OZ which corresponds to the connection of the selector CCS to which the tested connection set is connected. Any number of ports 07 numbered 00 to 24 can be connected to any number of ports numbered 1 to 50 (FIG. 11) which correspond to the connection sets belonging to the memory group served by each common memory control circuit. It can therefore be seen that the connection points OZ ₁ on one of which the 17.5 V pulse is transmitted to the common S expensive circuits of the memory are distributed like the connection sets that correspond to these connection points in the memory groups that these common control circuits correspond; therefore, a pulse arriving at a connection point corresponding to the connection set under test is transmitted to the respective common memory control circuit which corresponds to the memory group to which this connection set has access. As already indicated above, the connection points IZ, which correspond to the connection sets connected to the memories, are connected via two decoupling stages that use rectifier cells, as well as the voltage divider RSPT and coupling capacitor RSC to the grid circuit of the triode RSVx of the double triode RSVi [RSV2 , which is a double Amplifier stage forms. Each of these amplifiers changes the polarity of the pulse transmitted to it; thus a pulse of positive amplitude arises at the output, which is strong enough to ignite a cold cathode tube RSCT in the common control circuit of the memory.

A potential of around - 75 V is then applied between the anode of this tube and via the rsbz contact to the test lead RSF , which is used to check whether the circuit is tangible; this immediately prevents other call detection circuits from finding ground potential on this wire; thus all free connection sets over which this wire runs are temporarily made inaccessible.

It has been noticed that through reasonable division the connection sets on the various storage groups hit the facilities that the connection sets associated with each storage group can be sequenced be checked by the connection set finder, with a minimum between the individual checks time passes, and that the response of the cold cathode tube ASCT, which in the time segment takes place immediately following those where a free compound sentence has been found is sufficient takes place long before the period when the next set of connections could be checked, to prevent such a test from occurring.

Another consequence of the ignition of a cold cathode tube RSCT is that the relay RSB in the common control circuit of the memory picks up and indicates that the blocking of the other free connection sets has become effective.

The following response circuit of relay DEC in the common control circuit of the caller is closed: earth at the normally open contact rse ι (Fig. 11) (which checks the response of the cold cathode tube RSCT in the common control circuit of the memory), connection set (Fig. 10), call detection circuit ( Fig. 2), common control circuit of the detection device (Fig. 3), normally open contact FSi of the vertical selection stick, relay DEC, call detection circuit (Fig. 2), 500-ohm resistor and battery (Fig. 10). It should be noted that the circuit described simultaneously verifies both the presence of the office battery potential in the connection set under test and the fact that the shared memory control circuit is being used. When energized, the DEC relay (Fig. 3) carries out the following holding processes:

1. With its normally open contact decs it closes again .den Anissprechstromkreis of the delayed relay DEGB, which had been interrupted after the occupancy of the common control circuit of the call by contact of the ¹ J , in such a way that relay DEGB does not drop out.

2. With its normally open contact dec.4, it interrupts the response circuit of the DEB relay, the DEB relay then dropping out quickly. It should be noted that from the moment the cathode tubes ignite, the relay DjEF in series with the tube DEVD has been energized. The winding of relay DEB is short-circuited. Said relay DEB is given off-delay properties in this way and does not trip as long as the contact dec4 is not interrupted and the short circuit has cleared.

3. It applies earth to relay DEH via normally open contact dec 8 and normally closed contact del · 3 in such a way that said relay is energized as soon as relay DEB has dropped out. Relay DEH is held by contacts dehi and dec 8.

4. With the normally open contact dec 7 , it prepares a circuit through which an auxiliary rectifier cell can be switched on, as explained below.

When it drops out, the relay DBB removes the earth from the anode circuit of all the cold cathode tubes in the common control circuit of the call detector by means of its contact deb2; the said tubes go out and the anode relays de-energize, including those which through their contact caused the excitation of the vertical magnet CCSVM .

Since relay DEF has dropped out and relay DEH has picked up, a circuit is closed again via contacts deli2 and deh ^ to energize relay DEB , which in turn picks up with a delay caused by the release time of relay DEF and thus checks whether all cold cathode tubes have been extinguished and their anode relays have dropped out.

By pulling on the DEB relay, a

ίο hosted a second search, this time not for one free connection set, but to find the caller or one of the callers who can be connected to the selected connection set.

The wires running in each of the call detection circuits (Fig. 2), which are connected to the common control circuit, via the normally open contact dt 1 and the normally closed contact DHB.i are each connected via valves during each pulse

ao Pa 6 connected to the identification line CDIL . Five of these wires running over dt 1 are shown under the 20 wires that can be made available by the presence of the sources Pa, Pb and Pc.

As it is clear from the following description that the impulses coming from the call terminators via the CDIL wires act on the DEV 2 tube only when the DEC relay has picked up.

An explanation will now be given first of all for the tasks of the triode DEV4 on the right, which belongs to the double triode DEV ^ lDEV4 . During the first search term, that is, as long as relay DEC was in the rest position, the anode of this tube was DEV4 DECS connected via a break contact with the grids of the intensifier tube DEV2. The grid of the tube D EV4 is connected to the pulse source Pa 6 through a potentiometer DEPT 6 and a small capacitor DECNi ; said grid thus becomes positive only during every sixth time segment in a group of six time segments. Therefore, during these time segments the tube is conductive and the anode is relatively negative, so that it swallows all the pulses that may arrive during one of these time units, while the pulses corresponding to the sources Pa ι .. .Pa ζ , ie those to search for free Connection sets used pulses, not affected.

The impulses transmitted by the call terminator via CDIL are thus present during the first search (namely for a free connection set), but are rendered ineffective by the action of the DEV4 suppressor tube, as already described earlier. During the second search period, which must now follow, the suppressor tube DEV4 is separated by the normally closed contact dec 3, which now applies the source Pa 6 via a valve to the grid circuit of the amplifier tube DEV2 . As a result, any impulse, whatever it may come from, that is transmitted to the grid of the DEV2 tube during the periods Pax ... Pa 5 is now swallowed, and only those impulses that arrive during periods when the source Pa 6 transmits positive pulses , can act on the amplifier and regenerator stage.

If such a pulse is detected by the tube DEV2, the forwarded through tube Devi pulse corresponding ignites a combination of cold-cathode tubes DEVA, DEVB, DEVC, and the DEVD tube depending on the time period in which the pulse is received. In any case, in the group of DEVA tubes, only DEVAi can ignite and cause the DEAA relay to pick up, since a pulse that is sent out during the sixth time segment of a group of six time segments arrives in the first time segment of the next group of six time units.

It can now be seen that no circuit is closed for any of the vertical magnets CCSVM , since there are no contacts from relay DEAA in their response circuits.

Furthermore, a response circuit for a relay HR in one of the call detection circuits is closed via the working contacts deh.4, deaa 1 and via contact combinations of the anode relays DEBA ... DEBE, DEC A ... DECD of the cold cathode tubes, i.e. in the one whose pulses have been detected are. This relay closes a holding circuit via the normally open contact hr 1, normally closed contact ccshm 2, normally open contact dt 2, and earth. The switching of contact hr £ then removes the earth from the starter relay DES , which drops out to connect it to the normally closed contact DHB 2 and relay DEK in the common! To excite control circuit. The latter relay closes a holding circuit via the make contact dek 1, make contact dec 1 and earth and opens the response circuit of the relay DES elsewhere via its break contact dek 4; Furthermore, it closes a response circuit for the horizontal magnet CCSHM of the caller whose relay HR has picked up through its normally open contact dek 2. Relay HR is not energized in all other call terminators of the group, so that the corresponding horizontal magnets of these call terminators are not actuated. The horizontal magnet closes a holding circuit via the normally open contact ccshm2, normally open contact dt3 and earth; Via its normally closed contact ccshm 2 , it takes the earth from relay HR _1, which from now on can let go of its armature. The response of the relay has also caused relay DEB to drop out via its normally closed contact dek 5, so that said relay DEB drops out quickly and interrupts the anode circuit of all cold cathode tubes; the anode relays drop out and interrupt the response circuit of relay HR.

It should be noted that before contact dek 5 was interrupted, which caused relay DEB to drop out quickly, this relay was already short-circuited via contact defl , and consequently relay DEB begins to drop out slowly after the anode relay has been energized. Under these circumstances, DEB's fall time was sufficient

long to get relay Hi? through the Ensure anode relay.

The magnet CCSHM now moves the horizontal bar of the call detection circuit, and this closes the contacts A. .. B in such a way that a call detection circuit with a connection to be established is now connected to the selected connection set.

By moving the horizontal selector stick of the CCS selector, the contacts DHBi, DHB 2 of the call detection circuit (Fig. 2) separate the earth connections made by the contacts dt 1 and dt 3 to the common control circuit of the call detection device. The circuit now remains dependent on relays DEC and contact rse 1 of the relay RSE in the common control circuit of the memory (Fig. 11), until it is effectively checked that the connection set has actually been connected to the call detection circuit and that the common control circuit of the memory has received the instruction to connect to perform a free memory circuit.

This is because when a circuit is made across the selector .CCS "to lay the vertical magnet RSVM of the selector RS according to the selected connection set (Fig. 9, 10, 11), the selected vertical magnet RSVM in the The following circuit picks up: call detection circuit, earth on normally open contact dt 5, contact D of the selector CCS (Fig. 2), connection set (Fig. 10), normally closed contact ccbc 7, vertical magnet RSVM of the common memory control circuit (Fig. 11).

The attraction of the RSVM magnet closes the corresponding normally open contact rsvmi, which energizes the RSH relay. In the circuit: normally open contact rsvmi, normally open contact rshx, normally open contact rse 2 , relay i? 6 ".D 'is excited and is maintained via the normally open contacts rsd $ and rsvmi. Contact rsh6 interrupts the test circuit of the memory. If relay RSE is excited, Contact rse 3 shorts the winding of relay RSB and thus makes it drop-out delayed. Relay RSB has not yet dropped out, but the interruption of contact rse 5 removes the short-circuit and relay RSB drops out immediately.

When the contact rsbz is interrupted, the cold cathode tube RSCT goes out and relay RSE drops out. The occupied state on the test lead is maintained despite the fact that the cold cathode tube has gone out, because the contacts rsb 4 and rsh 6 are interrupted in this test lead RSF.

The drop in relay RSE means to the call operator that the common control circuit can be brought into the rest position, which is done by interrupting the normally open contact rse · χ in the circuit in which the relay DEC (FIG. 3) is energized. The drop-out of relay DEC opens the working circuit of relay DEH through contact dec 8 and the excitation circuit of relay DEK with contact dec 1; the actuated vertical magnet releases its armature as a result of the interruption of the contact dec 6. The vertical selector stick of the CCS selector returns to the rest position. The horizontal bar is held in place by the horizontal CCSHM magnet in the call screening ■ control circuit. Relay DEB has dropped out due to the interruption of contact dek 5 since relay DEK has ^: responded; contact del · 2 extinguished the cold cathode tubes and dropped their anode relays.

The drop in relay DEK in turn prepares the response ^circuit of relay DES via its contact dek 4, so that from this moment on this relay can pick up to service the next call. Relay DEB can only be energized again when the Normally open contact deft has canceled the short circuit of its winding, which ensures that relay DEB remains de-energized for a long enough time that the anode relays of the cold cathode tubes can de-energize.

The vertical magnet CCSVM has been kept attracted since the period in which the cold cathode tubes went out for the first time, that is, after relay DEB has dropped out, which takes place by breaking contact decj \. At the moment when relay DEC picks up The extinguishing of the tubes causes the interruption of the working circuit of the vertical magnet as a result of the failure of the corresponding anode relay, while the holding circuit runs via a working contact ccsvmi of the vertical magnet SSSVM, a contact dec 6 of the relay DEC and earth. This holding circuit is interrupted by the Contact dec 6 at the moment when relay DEC drops out, which is the case before relay DEK drops out, because the latter is held by a normally open contact of DEC . The starter relay DES can only respond for a new call when relay DEK drops out too is because a normally closed contact dek 4 is looped into the working circuit of this relay. At this moment it is not yet certain whether the vertical magnet has already returned to its rest position; but as long as this is not the case, a normally open contact ccsvm2, which belongs to one of these magnets that may have attracted , keeps the DEB relay short-circuited and thus prevents the DEB relay from being addressed for a new call connection as long as any vertical dial is still raised.

The fall of relay RSE in the common control circuit of the memory (Fig. 11) causes the search for a free memory circuit, because the common starting relay RSST responds and is excited via the idle contact rse 4 and the normally open contact rsd 4. Through the individual normally open contact for each Memory of a group, one of which is shown at rrst 1, a circuit is closed through which the individual starting relay Λ each free memory circuit (Fig. 13) can respond via the break contact HB 2 of the horizontal selector rod of the selector RS. By pulling in the individual relay St it is ensured that the battery potential is connected to the relevant memory and that this relay is ready

with its two working contacts st ι and st 2 the response circuits of the cold cathode tube HV in the memory circuit. The cathodes of all tubes of the free memory of a group are connected to the S negative pole of a 150 V battery (Fig. 11) through the normally open contact st2 and via a common 3000 Ohm resistor, the purpose of which is to ignite each to prevent more than one tube in a group. The normally open contact sti places earth on the control electrode via two 500-ohm resistors in series; one of the sources Ra 1 ... Ra6 (a different pulse source for each memory in a group) is connected to the common point of the two 500 ohm resistors via a rectifier cell TG . The control electrodes of the various tubes in a storage group therefore only come to a relatively positive potential when the source Ra connected to them is relatively positive, which is the case for the various tubes in a group at different times. In this way it is avoided that more than one tube receives sufficient voltage at its ionization path to ignite. The first tube that ignites determines the utilization of the associated memory, and by igniting its discharge space it reduces the cathode potential of the other tubes so much that they cannot ignite even if their control electrodes are relatively positive.

The memory circuit whose tube HV ignited

has, shall now be considered; Relay F pulls in series with the discharge path, and with its normally open contact / 1 it closes the response current circuit of relay Lb. This has the effect that the memory is made occupied by removing the earth on the test wire through normally closed contact Ib 4 and the connection of the connection set with the memory is caused by the working circuit of the horizontal magnet RSHM of the selector RS corresponding to the memory is closed as follows: Earth, working contact Ib 1. Contact / 2 closes "the response circuit of relay Fi, which is over Normally open contact / 14 and normally closed contact si.6 holds. Furthermore, when relay RSE drops out, relay RS-B is again excited in the common control circuit (Fig. 11) the connection between the memory, the horizontal magnet RSHM of which has been excited, and the connection set, the vertical selector rod w raised order is. The horizontal selector bar now interrupts its normally closed contact HB 2 and causes the individual starting relay St of the memory to drop. The drop in relay St causes the tube HV in the memory to go out and relay F to drop out; the delayed relay Lb begins to drop out slowly.

The closing of contact Ib 6 and contact HB 3 of the horizontal selector rod has actuated the relay Lh. Closing contact lh 2 closes the response circuit of relay B.

Relay Ch picks up in a circuit that contains contact b 3 in the energized state and contact ok 5 in the de-energized state.

Furthermore, by closing the contacts of the selector RS and by energizing the relay Lh ■ in the memory circuit, the response circuit of relay LFA in the call searcher circuit (FIG. 6) has been closed. This relay picks up because earth is applied in the memory circuit via the following circuit: normally closed contacts ok 5, Uy, normally open contact lh 5, wire IB of the connection set (Fig. 9, 10), 5-wire to the call search circuit (Fig. 6 ), Normally closed contact Ifhm 2, winding of relay LFA, battery.

The normally open contact If a 9 applies ground to the F wire so that relay CCBC in the connection set can respond, and this has the effect that the connection between the call detection circuit and the shared memory control circuit is canceled via the normally closed contacts ccbcj, ccbc $, ccbcg . Therefore the vertical magnet RSVM of the last-mentioned circuit (Fig. Iij drops out, and by breaking its normally open contact rsvmi it removes the earth connection from the response circuit of the relays RSD and RSH , so that they drop out. Contact rsd-4 drops the common starting relay RSST from; the vertical selector stick returns to the rest position. Contact rsdz closes the response circuit of relay RSB _1, whereby this relay is already excited by the rest contact rse $ . The common memory control circuit is now in the rest position, and through the normally open contact rsb ^. and the normally closed contact rsh6, the test circuit is restored after the remaining free connection sets, so that these circuits are accessible again, provided that one or more memories are free.

Relay CCBC in the connection set forms a circuit through its response, through which relay Lb in the memory circuit is kept attracted depending on the caller until the connection between the memory and the calling line has been switched through. The holding circuit for relay Lb runs as follows: earth, normally open contact dt 5 (Fig. 2), contact D of the selector CCS, normally open contact ccbc2, normally closed contact ccdaj. in the connection set (Fig. 10), contact OB of selector RS , normally open contact lh 10, normally closed contact It4, winding of relay Lb and battery.

A connection from one of the sources Pd ι .. .Pd ίο to the memory circuit can be established through contact A of the selector CCS in the call detection circuit; this connection would be used to indicate to the memory circuit the hundreds number of the group to which the calling line belongs, if the requirements of the central office make this necessary. This indication would be used to control the selection of a first pager circuit looking for free lines in that group by a second pager circuit which would operate in the same way as

the group selector would, under appropriate conditions, use the same common control circuit. Under the circumstances described, all busy circuits are held in the call termination circuit depending on relay DT. This relay keeps the horizontal magnet CCSHM of the selector CCS attracted via its normally open contact dt 3, via which the caller has reached a connection set, and through its normally open contact dt 5 it holds the relay Lb of the memory as described. The relay Lb in turn holds on the one hand the horizontal magnet RSHM of the selector RS via its normally open contact Z & i and on the other hand relay Lh through its normally open contact Ib 6, said relay Lh connecting the memory to the connection set through its contacts.

As already described, the memory circuit applies earth to the B wire and thus lets relay LFA ao respond via the normally closed contact Ifhm 2 of the horizontal magnet LFHM .

The attraction of relay LFA immediately causes the connection of the call finder circuit with its common control circuit by connecting the wires A, C and D of the connection. set via the normally open contacts Ifa $ or If0,2 or Ifa6, and the common control circuit comes into operation through a ground connection applied to it through the normally closed contact LFHB 3 and the normally open contact If α ι.

Relay LFA also builds a holding circuit over the jB wire in series with the winding of the horizontal magnet LFHM and the normally open contact If a 4, but the magnet LFHM cannot respond in the relevant time segment because both ends of its winding are earthed; a direct earth connection is actually made in the following circuit: £ wire, contact E of the selector RS in the memory, normally open contact Ihi (Fig. 12), earth. Earth is applied via the contact Ifag to the response circuit of the relay CCBC in the connection set (Fig. 9), and relay CCBC is thus energized, as already indicated.

The earth connection applied via the normally open contact If a 1 and the normally closed contacts Ifshx and Ifse 3 causes the relay LFSB to be energized in series with a resistor connected to the supply battery of the common control circuit; this relay closes its contacts Ifsb 1, Ifsb2, Ifsbz, Ifsb4, thus preparing the circuits that allow the call seeker to control the choice of the calling line. As already described above, the call detection circuit (Fig. 2) contains a generator tube VAD 4, which transmits pulses in its cathode circuit and in its grid circuit at the same time as the pulses coming from the line or lines connected to it.

The pulses received in the cathode circuit are fed to the common control circuit of the call seekers (FIG. 7) via wire III. A pulse is transmitted every 120 time segments in a certain period, said pulse being indicative of the tens and units of the calling line number; By closing the normally open contact Ifsbz , this pulse is transmitted via the normally closed contact If km ι, normally open contact If a 6 and the normally closed contact LFHBi to the D wire, which is connected to the memory circuit via the connection set.

It should be noted that in the memory control unit the contact /, 13 has the grid of the tube Vas connected to earth in the following circuit: normally open contact ch2, normally open contact / 13 and normally closed contact lay t and resistance 50 kOhm. The grid of the tube Vch.4. is also earthed via the normally closed contact fs 4 and 50 kOhm. None of the tubes Va2 and Va 4 can thus interfere with the pulses amplified by the tube Vai. The grid of the tube VaZ is connected to the pulse sources Pan , via the normally closed contacts Ot 4, si 5 and fs2 . .Pa 6 connected, which are connected in parallel via rectifier cells. The tube F & 3 thus allows pulses from the tube Va 1 to be received at any time, except when the pulse source Pa 1 is working, that is, during five of the six time periods that make up each cycle Pa dedicated to voter control.

During each of the impulses coming from the sources Pa2 ... Pa6, current flows from the central negative battery to the point with the potential -16 V supplied by one of the said sources through the grid resistance of Va 3 and the rectifier corresponding to the source concerned will. The grid is brought to -16 V for the duration of the pulses Pa 2 ... Pa 6, so that the tube Va 3 is then conductive. But during each of the periods given by source Ρα. ι delivered pulses delivered a potential of -40 V to the grid of Va 3, and said tube is then no longer conductive. During the pulses Pa 1 there is therefore a negative potential at the cathode of Fa 3, and the pulse generator cannot be operated by pulses from a common control circuit during - the pulses Pa 1 via the D wire, * ■

Pulses from a source d ?, are constantly applied to the grid of the tube Vo 2 belonging to a double triode F01 / F02, which is intended to generate pulses. If one or more of the cathodes Fen, Va2, Faß, Fa, 4 is or are negative, the pulses d 3 are all swallowed up in a 20 kOhm resistor, because the said 20 kOhm resistor and the rectifier Rc i , Rc2, Rc3 and Rc4 and the negative cathode or cathode of the tubes. Current flows. If the pulses are applied simultaneously by the call seeker and the sources Pa 2 ... Pa 6 to the grids of the tubes Va 1, Va 3, sq all cathodes are positive at the same time, and the corresponding pulse 0 * 3 X20 makes the grid of Vo 2 positive, because no current flows through the 20 kOhm resistor and one of the rectifiers.

Therefore the tube Vo 2 causes the response of the tube Vo 1. The tube Vo 1 belongs to a pulse regenerator which also has a transmitter

TP / TS , which lies between the anode and grid circuit, has a resistor RRS and a varistor or thermistor TH parallel to the grid bias and cathode circuit. As long as there is no triggering pulse, the grid of the generator tube Vo ι is so strongly biased that the tube is blocked and no current flows neither in the windings of the transformer TP / TS nor in the tube. If suddenly negative voltage is applied to the anode of the tube, this voltage changes its sign after it reaches the grid winding of the intermediate transformer, so that said grid then becomes positive. When the amplitude of the applied voltage is large enough to bring the resulting bias of the grid to a suitable value, the generator starts up. Anode current begins to flow through the anode winding; the grid becomes more positive and, conversely, causes an increase in the anode current. Almost immediately, the grid becomes more positive than the cathode. Considerable grid current begins to flow and thus prevents any further increase in grid potential. At this moment the anode and grid currents begin to decrease, the latter even faster than the former, so that the difference between the ampere-turns of the anode and grid windings increases rapidly.

After a period of time, the duration of which is largely dependent on the self-induction of the transformer windings and the resistance of the anode circuit of the tube depends, the grid current has become zero. from From this moment on, any decrease in the anode current causes negative voltage to appear in the grid winding, which in turn causes a further decrease in the anode current. The tube is then blocked quickly and remains blocked until a new trigger pulse arrives.

This creates a current pulse of practically rectangular shape in the cathode circle, its amplitude and duration depend neither on the amplitude nor on the shape of the triggering pulse.

The load resistor RRS in the cathode circuit of the generator makes it possible to convert the current pulse into a voltage pulse, said voltage being kept practically at the same value for the entire pulse duration. For each trigger pulse applied to the anode, a pulse is generated, whereupon the tube returns to the rest position.

When a dialing pulse from the caller arrives via the Z) wires in the memory on the grid of the tube Va, ι, an amplified pulse is applied to the grid of the tube Vo 2 . When the amplified pulse and a short pulse ^ 3 coincide at the grid of the tube Vo 2 , a pulse is transmitted through the tube Vo 1 and applied to the cold cathode tubes Vabu, Via, Vib, Voa ... Voh . The Vabu tube is the tube that indicates that it is occupied by its electrical state; it is only used in the case of line selectors and its circuit is interrupted by contact fs 5.

The tube Via is switched on and receives no control pulses, so that it responds and lets its anode relay Si attract. The tube via is separated by contact ph 5 and cannot respond.

The tubes Voa ... Voh are now controlled by other pulse sources from the cycles Ra, Rb, Rc , the source Rai occurring each time, so that no tubes responding to line classes will respond under the influence of the dialing pulses.

Relay Si causes relay F 1 to drop out, so that! the earth connection applied to tube Va 2 disappears.

Contact si 4 places a ground connection on .the normally closed contacts it 5 and or 1, which allows relay Ot to respond; Relay Ot is held via its contact ot2 . The regenerated pulse, which, because of the temporal position of pulse d 1, falls in the time segment immediately following that where it was transmitted to the caller, is transferred to the cold cathode tubes LFSVAi ... in the common control circuit (FIG. 7). LFSVΆ 6, LFSVB ι ... LFSVB 5, LFSVC 1 ... LFSVC 4 and LFSVD given in the following circuit diagram: Working contact Ih ^, C-core, break contact ccdaZ in the connection set (Fig. 9), C-core, break contact LFHB 2 in the call searcher circuit (Fig. 6) and normally open contact If a 2.

The tubes respond in a combination which is indicative of the tens and units of the number of the calling party, while the LFSVD tube responds with each pulse.

Each of these 15 tubes is dependent on a system of rectifiers, each with one of the Pulse sources (the timing chart and arrangement of which are shown in Fig. 21) are connected in such a way that these tubes can only ignite at very specific times.

For example, each of the tubes LFSVA 1 ... LFSVA 6 is dependent on one of the sources Ra 1 ... Ra 6 via a valve arrangement, specifically in such a way that the tube LFSVAi can only ignite in one of those time periods when the source Rai is relative emits positive impulse, i.e. in the time segments 1, 7, 13 etc.

The tubes LFSVB 1 ... LFSVB 5 are each connected via a valve to one of the sources Rb 1 ... Rb 5, so that the tube LFSVB 1 can only ignite in one of the time periods when the source Rb 1 is relatively positive Impulses transmitted, ie during the period 1. .. 6, 31 ... 36, 61 ... .66 etc.

The tubes LFSVC Ί .. .LFSVC 4 are quite similar from the sources Rc Rc 1 ... 4 dependent, and in FIG. 21, it is easy to find the time periods where these sources give positive impulses from him.

Finally, there is also a LFSVD tube that is not dependent on any valve and therefore ignites under the influence of any pulse coming from the memory via the C-wire at any point in time. It is easy to see that an incoming pulse at any point in time always triggers one tube in each of the three groups

LFSVA, LFSVB and LFSVC have the effect that a combination of one tube in each of the three groups is characteristic of each time segment and so in turn for the calling line. For example, according to the table (FIG. 22), time segment No. 1 is used to send a pulse identifying line 00, and this pulse is passed on from the memory in time segment No. 2. At the moment when the sources Ra2, Rb ι and Rc τ are relatively positive, the tubes LFSVA 2, LFSVBi, and LFSVCi ignite. '■

Similarly, a pulse transmitted in time segment No. 119 to identify a call coming from line 99 arrives at the cold cathodes, tubes in time segment No. 120, ie at the moment when only sources Ra6, Rb 5 and Rc 4 are relatively positive so that the tubes LFSVA 6, LFSV B 5 and LpSV C 4 ignite. Each of the ignited tubes causes its anode relay to respond; through the working contacts of these three relays, the current flows are closed in such a way that the connection is determined to which the respective call searcher circuit must be controlled.

- First, the response circuit of one of the vertical magnets LFVM of the multiple selector is closed by the current flows that are dependent on the anode relays LPSAA ... LFSAF, LFSBA ... LFSBB , LFSCA ... LFSCD, as follows in connection with the line selector should be described.

One of the relays LFSD or LFSE is energized because one of the relays LFSCA ... LFSCD associated with the tubes LFSVC 1 ... LFSVC'4 has picked up. Relay LFSD picks up depending on one of the relays LFSCA or LFSCB via a response circuit that contains the contacts Ifscaz or Ifscb 2; Furthermore, relay LFSE picks up because its excitation circuit is closed by contact Ifsee 2 or Ifscd 2 of relays LFSCC or LFSCD.

The energization of the perpendicular magnet LFVM causes the perpendicular rod, which is dependent on the perpendicular rod actuated by the attracted perpendicular magnet, to be pushed upwards.

Meanwhile, two more processes are taking place. On the one hand, after receiving the information that the selection directives have arrived, as already mentioned, the circuit of the test relay T via normally open contact oti, normally closed contact It 3, normally open contact lh 4, wire LA, A wire of a connection set and in the caller Normally open contact LFHB 4, normally open contact If a 8, relay LPSC (Fig. 7), relay T picks up and switches on the double test relay Dt ; only such a relay can pick up, so that only one memory can be connected to one and the same line. The response circuit of relay Cs is closed by contact dt 4. The interruption of the two contacts ot6 and dt ^ causes the tubes Voa ... to extinguish completely, as far as they have ignited, and causes the associated relay to drop out, so that the contacts oa 3. . . oh 3 and the normally open contact it responds to 2 relays Or and relays Ot to waste. In each .Speichercontrol device that has not brought it to a connection, the previously activated relay T drops out as a result of the response of relay Dt in that memory that has reached a connection. The relay Cs and Or draw in those memories not on, which are not connected with a line, and relay B is short-circuited applied by the ground connection, which on the one end of its winding on the normally closed contact 1 1 and and the normally open contact ots. Relay B drops out and releases relays Si, Ot and Ch . Relay B picks up again via contact lh 2 , and the memory is again ready to receive pulses from a calling line. In the common control circuit of the call seeker, the relay LFSC picks up , the winding of which is low ohmic due to the presence of test potential, and closes a holding circuit for one of the relays LFSD 'or LFSE ₁ that has attracted, so that this relay is then made independent of the anode relay of the storage tubes.

Furthermore, relay LFSF picks up in series with tube LFSVD, and this relay short-circuits the winding of relay LFSB, which then slowly begins to drop out. Before relay LFSB has dropped out, relay LFSC can respond and, with its contact Ifse 3, open the response circuit of relay LFSB , which then drops out immediately. When it drops out , relay LFSB interrupts its contacts Ifsb 1 and Ifsb 2 and thus interrupts the anode circuits of all tubes, so that those that have ignited go out and their anode relays drop out. .,

The response circuit of the vertical magnet LFVM is then interrupted; but this magnet remains excited in the following circuit: working contact Ifvmi, contact lfsd $ or Ifse ^. A relay LFSH that picks up interrupts the circuit from relay LFSB to contact Ifshi. -

After the identity of the calling line has been determined in this way, a test is first carried out to determine the line class. For this purpose, the connections numbered 00 ... 49 or 50 ... 99, ie one connection point per line, are connected through any desired grouping method with 20 line class cores COL , depending on the class to which each of the lines is to belong .

Fig. 8 shows under the heading distributor connections for line classes a table which indicates with which of the wires COLi ... COL 20 the different lines must be connected according to their class.

When the vertical magnet of a pair of connections is actuated, the end is applied to the wire COL via a common normally open contact Ifsdi, or If se Z and one of the 50 parallel contacts LFVB 1, LFVB 2jxsw., Which belong to the vertical selector rods.

As shown in the drawing, the 20 connection points are each connected via a high-resistance COR with three successive valve stages CORCS, CORCP, BRCS, BRCP, CRCS and CRCP, which are dependent on the pulse sources , so that earth can be applied to any of these wires causes a pulse at a corresponding point in time, said pulse on the grid of the amplifier tube SlΆ 3

ίο is transmitted. The period of time where this impulse is applied for a certain number of the 20 connection points in that shown in FIG Table given.

It can be seen that all of these time segments are in each case. correspond to the last time segment in the 20 successive groups of six time units each within a group of 120 time units which are defined by the sources Pa, Pb and Pc . The first valve stage, on which all connection lines of the 20 line classes depend, is always connected to source Pa 6 for each class. Since relay LFSC is picked up , the source Pa 6 is also connected to the grid of the amplifier tube via a valve via the normally open contact Ifse 1, so that those pulses are suppressed that arrive at different times than those with the 20 wires already mentioned COL are linked.

An earth connection is then made to one of the 20 connection points via one of the contacts on the vertical selector rod that corresponds to the selected line, according to the line class. A pulse is then transmitted in the corresponding time segment to the amplifier tube SVA 3, which then becomes conductive because a battery is connected to its cathode via the normally open contact Ifse 4; the cathode potential is then such that the tube can respond to the pulses. These pulses are combined with a short pulse transmitted by source dz, which is transmitted to the grid of tube SVA 3 via a small capacitor GCi , so that said tube is triggered once every 120 time units. The exact time of this triggering is determined by the pulse transmitted by source α "2, which, as can be seen from FIG. 21, lies towards the end of the time segment when a pulse is transmitted by the valves.

By means of a second double triode SVAi / SVA 2, the anodes, cathodes and grid of which are parallel, and in cooperation with a transformer LFST with two windings, a pulse is emitted again, said pulse starting at the moment when the source d-2 gives a short one Impulse transmitted and about half as long as a period of the source Pa 1 lasts. It is then clear that this pulse begins somewhat before the end of the time segment where a temporal pulse is generated by the rectifying system and that it continues into the following time segment.

This impulse is now transmitted through the normally closed contact Ifsb Z of the relay LFSB (which has dropped out in the meantime) of the D-wire def An call-seeker circuit and then fed to the grid of the tube Va 1 of the memory circuit in the following way: Contact Ifhm 1 in rest position ( Fig. 6), normally open contact Ifa6, normally closed contact LFHB i, D wire, connection set to the memory; the memory responds to this impulse by determining the period of time when this said impulse arrives and thus determines the class of the calling line. The memory records the line class in the following way:

The grid of the tube Va 2 is connected to earth via the make contact cli2 and make contact or2. The grid of the tube Va 4 is in turn via the normally closed contact fs. 4 laid on earth. The grid of the tube Va 3 is connected to the source Pa ι via the normally closed contact ot4, normally open contact si 3 (where contact si 5 is interrupted), so that tube Va 3 is blocked during all pulses transmitted by the sources Pa 2 ... Pa6 ; Said tube Γα 3 can respond to impulses only during the time when source Pa 1 emits impulses, which only enables the determination of impulses which characterize the line class.

When a pulse of this type is detected, the tube Va, 1 responds and applies an amplified pulse to the grid of the tube Vo 2, so that the tube Vo 1 and the transducer TP, TS one depending on the detecting source α ⁷ 3 Transmit the impulse on the Γ-wire at the beginning of the period immediately following the one where the impulse arrives. The transmitted pulse has no influence on the common control circuit of the call seekers, but it causes a combination of tubes and relays characterizing the line class to respond in the memory . Voa ... Voh, Oa.-. . Oh, which in the case of an ordinary line consists of relays Oa and Oe . Relay Or drops out.

Relay OK now picks up in the following circuit: normally closed contact 0 * 5, normally closed contact bu 3, normally open contact dt2, normally closed contact ph6, normally open contact oe4, normally open contact oai; the interruption of contact ok 5 removes the earth from wire I B.

The horizontal magnet of the call seeker responds in series with relay LFA via the earth applied in the following circuit: E-wire, normally open contact Ihi in the storage circuit. Contact lfhm.2 is interrupted, relay and solenoid LFA LFHM separates from the i? Vein and reports the same time that magnetic LFHM is energized memory. Relay Ch in the memory drops out, and the memory then applies earth to the D wire in the following circuit: make contact dt4, make contact csi, break contact oh i, make contact 0 ^ 4. This ground connection is applied to the common control circuit (Fig. 7) via the normally closed contact LFHBi, normally open contact If a 6 and normally open contact Ifhmi and thus causes the two horizontal auxiliary magnets LFSHMA or LFSHM B to respond, depending on whether contact Ifsdz or Ifse 2 is closed . In the event of a call coming from line 00, relay LFSD is energized, and thus the electrical

magnet LPSHMA on; in the case of a call coming from line 99, relay LFSE ₁ energized and thus it is magnet LFSHMB that picks up . Therefore a horizontal rod of the seeker whose horizontal magnet LFHM had already been excited is pushed to the left or right; in the first case the caller switches on the line 00 and in the second case the line 99.

When the five contacts A ... E leading to the calling line have been closed, the normally closed contacts LFHBi, LFHB2, LPHB 3 and LFHB 4 open by moving the horizontal bar, while the normally open contacts LFHB1 and LFHB 2 close at the same time. This brings the call searcher circuit into the call state and at the same time separates it from the common control circuit.

It should be noted that, depending on the case at hand, one of the magnets LFSHMA or LFSHMB (Fig. 7) closes its holding circuit : normally open contact of magnets Ifshma 1 or Ifshmb 1 and a contact on one of the relays LFSD or LFSE that has responded so that the horizontal auxiliary magnet does not drop immediately if the break contact LFHBi in the line circuit is interrupted. Furthermore, and due to the interruption of the normally closed contact LFHB 4 , the relay LFSC in the common control circuit drops out, as do the test relays T and Dt, which are switched on in the memory by the yl wire; Contact dt 4 interrupts and releases relay Cs . The waste · relay Cs caused by it 3 waste of relays OK. Relay Dt with its contact dt 4 removes the earth connection on the 'D wire.

The drop-out of relay LFSC pulls that of relay LFSD or LSFE with it, which causes the vertical as well as the horizontal magnet LFSHMA or LFSHMB to go into the rest position. The common control circuit is now in the idle state and can devote itself to establishing another connection because relay LFSB can respond. It should be noted that the fall of the horizontal auxiliary magnet LFSHMA or LFSHMB does not return the horizontal selection rod of the call seeker to the rest position, because it is also kept attracted by the horizontal magnet LFHM, which belongs to the call seeker circuit (Fig. 6).

In the memory, the drop in relay Cs and the response of the relay corresponding to an ordinary subscriber line causes relay Lt to pick up via the following current flow: normally closed contact lay, normally closed contact cs%, normally closed contact // 4, normally open contact 054, normally open contact oai. Relay Lt maintains the following contacts: It 1 energized and IM2, energized.

Relay CCDA responds in the connection set depending on the memory circuit when the latter has switched through the connection with the calling line. The response circuit of relay CCDA is shown below.

The common control circuit of the call seeker and line selector can supply any number of individual call seekers and / or line selectors at the same time, so that it carries out its dialing activity for several calling and / or desired lines at the same time, the line being selected in each case by a memory that records each connection performs. Accordingly, it can be seen that the individual call searcher switches and line selector switches are not occupied when one of them is used to select a line with the help of the common control circuit, so that any number of other call seekers or Line selectors can be used for other calls; If this is the case, then these call searcher and line selector circuits are all connected in parallel to the common control circuit through the response of their respective relays LFA and FA. The common control circuit then sends the information coming from the search circuit simultaneously through all of the call seekers and line selectors connected to the corresponding memories. If one or more of the said memories responds to the impulses coming from the search device and returns an impulse via the C-wire, the cold cathoid tubes respond in the same way as already described.

Relay Si attracts in the manner already indicated in two or more memories which have responded simultaneously to the pulses coming from the search device; each of the said memories then applies the two test relays D and Dt to the .'i wire. These test relays cause a double test process in a well-known manner, so that these relays can only pick up in one of these memories and ultimately close their contacts in order to continue the switching processes already described. In the other memory or the other memories, where the test relay could not respond immediately, a circuit is closed via the normally closed contact 1 1 of relay T and normally open contact 0 ^ 3, which causes a short circuit of relay B ; this relay, which is energized via contact lh 2 when the memory is occupied, then slowly drops out. When it drops out, it removes the earth connection of the anode circuit of the tube Via , so that relay Si drops out. The memory will then be reset to the dial position and dialing will begin again.

It has been declared the common Control circuitry to select and search for multiple call seekers and line selectors at the same time can perform. As soon as the cold cathode tubes receive a dialing directive for a call connection have recorded, this requires that the memories, the other connections in the use the same multiple selector, a message is sent that the selection should stop; therefore can there is no confusion caused by two or more memories trying to use their cathode tubes one after the other the dialing information regarding the connection with which it

are busy recording at a time when the cold cathode tube !! are already busy recording or before they are ready for the next recording. This is done by the LFSVD tube in cooperation with the SVA 4 triode, which works as a suppressor tube. If the LFSVD tube ignites at the same time as a combination of LFSVA ... LFSVC tubes, it changes this as a result of a connection

ίο with the negative pole of a 150 V battery via the winding of relay LFSF and an individual resistor originally - 150 V cathode potential now from by bringing it to around - 75 V. The cathode of the tube LFSVD is connected to a point of a voltage divider LFSPT via a rectifier cell LFSRD. The potential of said voltage divider point is normally - 142 V. The voltage divider is on the one hand with its two ends with the negative pole of a 150 V battery or the positive pole of a 50 V battery and on the other hand in another point with the grid of Suppressor tube SVA4 connected; this point is normally at -21.5 V. A second variable voltage divider APT applies a potential of 20 V through the rectifier cell ARC to the grid of the tube SVA4 and thus prevents this grid from becoming even more negative.

When the grid of the amplifier tube SVA 4 is at -21.5 V, the cathode is held at a potential near it; this potential is also transmitted to the cathode of the amplifier tube SVAs , which under these circumstances can respond to the pulses transmitted to its grid via the various rectifier cell systems.

When the tube LFSVD ignites, the potential of the voltage divider LFSPT is raised from the original -142 V to -75 V. Therefore, the potential of the voltage divider point connected to the grid of the suppressor tube SVA4 is changed in such a way that it is raised to about ο V and therefore the cathode of this tube is at about the same potential. Furthermore, the cathode of the amplifier tube SVA 3 is raised to about ο V and therefore opposite the grid. strongly positive, so that from then on the said tube no longer transmits any impulses that could still arrive from the line selector while searching for a desired line. At the same time, the cathode of the suppressor tube SVA 4 is connected via the I wire to the call detector (Fig. 2), where it also acts on the cathode of the suppressor tube VAD2 and then prevents the transmission of pulses from the pulse regenerator tube VAD4 on wire III. If, therefore, other lines in the same group of hundreds would call at the same time, they could not transmit their dialing information, ie the impulse which characterizes the tens and ones digits of their call number, to the other call seekers or other memories. It should be noted that when relay LFSC picks up and relay LFSB drops out, tube LFSVD goes out at the same time as the other cold cathode tubes. The impulse transmission to the line selector is then prevented because contact Ifse 1 applies the impulse source Pa6 to the grid of the amplifier tube SVA 3 via a valve, so that from this moment on only those impulses can be transmitted that arrive in time segments that are relevant for the line class are characteristic.

Furthermore, the transmission of dialing pulses in the call seekers is prevented because wire III is cut off by the contact Ifsb 3 that has dropped out.

Tube LFSVD can also go out at the moment when relay LFSB drops out because, as already explained, its task has been transferred to another tube.

If a call appears on a line, impulses are sent by the call terminator on wire II and impulses are transmitted simultaneously on wire III; these pulses are indicative of the tens and units of the calling line number as a whole. The pulses transmitted via wire II are sent through a pulse generator tube VAD4 and made in the call detection circuit (Fig. 2) dependent on a short pulse dl which is applied to the voltage divider CDT and is timed so that it begins a little earlier than that of Tube SVA 3 in the common control circuit of the line selector depending on the short pulses 0.2, (Fig. 7) regenerated pulses. Furthermore, the pulses regenerated on core II are also somewhat longer than the pulse regenerated by tube SVA ¹ S , so that they end a little later. The pulses on wire II are fed via a rectifier cell to a point on the voltage divider LFSPT (FIG. 7) which is normally at -39 V; the potential of this point is shifted by the pulses in such a way that the suppressor tube SVA 4 shifts the cathode potential of the amplifier tube SVA 3 so that it becomes positive with respect to the grid of said tube.

In this way, the one in the common control circuit becomes that for the calling line characterizing period of time, the resulting impulse is completely suppressed. Therefore, a memory that supports the Search of a line selector for a line that has already picked up controls none Pulses in the time segment characteristic of the line in question, and therefore it is not in able to make the dialing as long as the calling line has not yet passed through a call finder has been found. From this moment on, however, the line is usually busy, and a memory which controls the search for such a line receives a busy signal, as for the line selector is described.

A release of the call connection is characterized at any time by the fact that the earth is removed from the £ wire, which causes the relay LFA and magnet LFHM to drop out when the latter has attracted. The fall of the latter causes the return of the horizontal dial

rods in their rest position and thus the separation of the contacts A ... E and the renewed closure of the rest contacts LFHB ι ... LFHB 4.

When the caller finds the calling line, the battery potential is transferred to the C-wire of the subscriber line, because the battery is connected to the C-wire of the caller via the normally open contact If a 7 and a 240-ohm resistor. The line is then no longer in the call state, and from this moment on no more impulses are transmitted from this line to the call terminator; therefore the impulse regenerator stops working and relay DT drops out.

However, it can happen that at this moment another subscriber line a call is transmitted, and that line then continues to send its impulses to the call operator and the regenerators then continue to work.

In this case, in order to cause the momentary drop in relay DT and thus bring the selector CCS to the rest position, from the normally open contact cc da 3 in the connection set (FIG. 10) via the contact E of the selector CCS and the normally open contact dt 2 (Fig. 2) applied to the cathode of the left amplifier tube VAD ι the call detection circuit earth.

The amplifier tube VA D 1 then stops conducting, so that the regenerator acting on relay DT is also blocked and relay DT drops out.

The interruption of contact df 3 causes the fall of the horizontal magnet CCSHM and the return of its horizontal selector rod to the rest position; contacts A .. .E are interrupted and the connection between the call terminator and the connection set is canceled.

The earth applied to the cathode of the amplifier tube VAD 1 is disconnected by contact dt 2 from the moment the relay DT drops out; but as soon as contact dt 3 has interrupted the response circuit of the relay, said circuit is only closed again by the normally closed contact DHB 3 when the horizontal rod has returned to the rest position, so that relay DT can only be excited for another conversation if this the case is.

The maintenance of the call is now completely dependent on relay Lb in the memory; said relay is no longer excited by the call detection circuit, but is now held by the attracted contact is 1 dependent on relay Is in the memory circuit; Relay Is energizes in series with the subscriber loop of the caller as soon as relay Lt has picked up and its contacts It 3 and It 7 have closed.

When relay Is has picked up, the caller is sent the signal via the DTC transmitter that the memory is ready to accept dialing information; said dial tone is suppressed when the first dial pulse arrives, as is well known in the art.

A calling line is always free and can send any line class information like them 8 are listed in the table on the left. If the transmitted line class information is a normal Identifies subscriber line, the memory control device is, as already stated earlier put into a state in order to receive pulses from the group selector in response to this message obtain. -

If the line class information received corresponds to the time unit no. 12 and means a line with limited switching authorization, the relays Oa and Of pick up . The earth connection created via the working contacts oay and of 2 causes relay Rs to respond, which is maintained via the working contact rs 1 and working contact IM 2. The response of relay Rs causes a control process in a well-known manner based on the selected by the caller and from Memory recorded number; Said relay then causes the transmission of a busy signal to the calling line or causes an officer to be called if the subscriber with limited switching authorization has dialed a number to which he is not authorized.

If information is received from the management of a participant who is away for a long period of time, the relays Oa and Og pick up . The earth applied via the working contacts σα 6 -and ogj energizes relay Lp, which is held via the working contact Ipi and working contact IhI 2. The attraction of Lp immediately gives a signal to a civil servant in a well-known manner.

If second call seekers were used, the memory would be set from the beginning so that it can control the second call seeker on the basis of a time pulse which identifies the hundreds digit and is sent out by the call detection circuit. The line class information coming from a second call seeker would cause relays Oc and Oe to pick up, and in this case the operating circuit of relay F 1 would depend on the normally open contacts of relays Oc and Oe and not, as described, on normally open contact F. ; Contact // 3 puts the grid of the tube Va 2 to earth and prepares the dialing processes of the first call seeker in the manner described above.

The dialing pulses which identify the number of the desired line are after any well known procedures and stored.

When relay Lt is energized, an earth connection established via make contact ItS, make contact lh 6 and wire CAL allows the excitation of relay CCDA in the connection set (Fig. 10). Relay CCDA enables the C and D wires of the memory to be connected to the outgoing C and D wires via the contacts ccda ^ and ccda2.

The purpose of a group selector circuit is to select a free port in a dependent Line group selected from a memory of several line groups according to the associated To cause the dialing digit of the number of the desired subscriber.

This circuit is based on the use of a multiple selector that has a certain number Contains horizontal voting sticks, each of which is considered to be the equivalent of a voter or single voter who treats a conversation in a manner like a voter of the well-known Kind with one movement only in one direction ·. For example, ioo connections are provided that are accessible to all individual voters together and to said voters. Vertical bars are also present that cross all horizontal bars and control the choice of a particular connection, which can be connected to an individual selector by means of a horizontal selector stick belonging to it target. The mode of operation of the multiple voter will be described in more detail in a moment.

A multiple selector of this type is used in the case of 100 connections; a certain number of individual voters is provided, which varies according to traffic requirements; everyone is like that arranged so that it can be used individually to connect to an available port.

Each of the voters has a voter position for himself with a horizontal magnet HM (Fig. 16), which sits in the multiple selector and a relay GA.

A common control circuit is provided for all individual group selectors of a multiple selector. This circuit can be periodic by using tubes and a certain number Cycles of electrical impulses depending on a memory free selection and / or dialing processes in one perform the single selector and move a vertical and horizontal selector stick of the Cause multiple dialers to switch through the connection path used by the call, when the connection has been seized. The choice of a free connection in a certain group happens depending on the first digit in the desired phone number. A free line voter is chosen from ten different groups of voters, for example each of the said Voter 100 lines coated. This choice is made depending on the hundreds digit you want Call number as it has been stored in the memory controlling the dialing.

Following a different procedure, the choice may be dependent from the memory without any direct relationship with a specific dialing number, but rather than one of a variable number of dials made by a combination of digits is determined by a well-known method.

The 100 connections can be used in any conceivable Divide them into any number of groups, usually ten. This number is not limited in any way. The number of line groups can be modified as required according to the needs; the The number of connections allocated to each group can be adjusted according to traffic requirements Modify as desired, and the connection contacts used for each of the groups can be without pick out any binding to rules from the 100 available connections and put together.

The devices and the circuit of the common control circuit are always the same and does not depend on how the connections are distributed to the individual groups.

In the common control circuit of the group selector, the precautions are taken so that for each connection through an easily relocated connection a class specification selected from among different ones can be allocated. The common control circuit is so arranged that they Specification can transmit the memory that sets up the call.

The earth applied via contact ok ζ of the memory (Fig. 12) causes relay GA in the group selector to respond in the following circuit: earth, break contact 0 & 5, break contact ei 3, make contact It 4 , make contact lh 10, contact OB of the multiple selector RS, wire OB and in the connection set (Fig. 10) normally open contact ccda ^, B wire (Fig. 9j and in the group selector (Fig. 16) 5 wire, normally closed contact hm 2 of a horizontal magnet HM, relay GA and battery.

When energized, relay GA immediately causes the group selector hold-down to be connected to the corresponding common control circuit by connecting wires A, C and D to said common control circuit via the normally open contacts ga8, ga2 and ga6.

Furthermore, relay GA builds a holding circuit via the £ wires in series with the winding of the horizontal electromagnet HM and the normally open contact ga4; Said electromagnet cannot attract at the moment under consideration, because earth is directly at both ends of its winding, in that the -Ε wire is actually earthed directly via the contact ccda ^ (Fig. 9j.

The common control circuit is put into the operating state by applying earth to said common control circuit in the following circuit: normally closed contact HBi, which belongs to the horizontal selector rod, normally open contact ga 1, normally closed contact ghi, normally closed contact gc ^, relay GB, resistor and battery. Relay GB in the common control circuit picks up and via its contact gb.i it applies earth to the anodes of the cold cathode tubes VRA ₁ VRB, VRC and Vd; Via its contact * gb 3 it applies -150 V to the cathode of the left part SVΛΖ of the double triode DAVzI DVA4; it prepares the dialing control circuit via the group selector for a connection in the desired group.

A resistor Rg of 100 kOhm is provided in the common control circuit for each of the 100 connections that can be reached via a selector group, with one end of this resistor being connected to the next selector stage via the F wire. When the connection is free, the F wire is grounded directly via the normally closed contact 'fa 3 (Fig. 19) belonging to the line selector.

If the resistor Rg belonging to a connection (Fig. 17) is grounded, there is actually the possibility

Ability to a current flow from this earth point to a point with a potential of -40 V via three successive stages of rectifiers ARCSj BRCS and CRCS one behind the other and other rectifiers ARCP, .. DRCP, which are each in the shunt branch. Said potential of -40 V comes from a voltage divider CPT located in the common control circuit; this potential is also applied via a high resistance ORH to the grid of an amplifier tube SVA 3, which forms one of the elements of a double triode SVA 3 / SVA4 . The rectifiers ARCP ... DRCP are connected to current sources, as already described Current can flow from earth on the P wire to the voltage divider OPT and from there to the grid of the SVA 3 tube only if this potential of -16 V is applied to all three rectifiers ARCP, BRCP and CRCP at the same time, which are connected to the search circuit coming from the P-wire of a connection. If the potential of said sources or even one of them is -40 V, then this potential is in effect on the connection circuit, which comes from the resistor Rg of the common control circuit of the group selector leads to the voltage divider OPT , since said potential can be transmitted via one of the rectifiers in the branch, e.g. ARCP , which in this case has a ni The resistor Rg swallows the potential difference between the earth at the I ⁷ wire and the source (-40 V) connected to the rectifier in the branch and no current flows after the voltage divider. The rectifiers in the shunt branch thus act as valves that enable or block the connection with the voltage divider OPT; current can flow to the voltage divider only if this connection is made possible by systems of -16 V from all associated sources. As a result, current can flow from earth to the voltage divider only if all of the valves which are decisive for the connection leading from the resistor Rg of a certain connection to the voltage divider OPT are permeable. Thus only at this moment the potential of the voltage divider and consequently that of the grid of the tube SV Aß can come to -16 V because of the corresponding values of the various resistors connected in the circuit, provided that the connection is free, i.e. supplies earth potential.

As trian now sees, the three sets of sources Pa, Pb and Pc are connected to the valves in such a way that said rectifier systems pass current for each of the 100 connections at a different point in time; when a connection connection is free, it transmits pulses to the grid of the tube SVA 3 at a point in time indicative of the connection in question. The way in which the various valves which enable this result to be achieved for the various connections numbered from to 99 must be interconnected, is shown in the table in FIG. 22, which also shows the times at which the pulses transmitted by each of the connections correspond. It can be seen that this table relates to time segments numbered in sequence from 1 to 120, the precautions being taken so that the sixth segment of each group of six has nothing to do with a call connection, with only 100 connections for a total of 120 connections the 100 connecting lines are used. Each connection to a group selector is connected in the common control circuit (FIG. 18) to its own valve, which in turn is connected to one of the sources Pa 1... Pa 5. Each of the successive groups of five of connections, which correspond to the time units ι ... 5, 7 ... 11 etc. and are connected to the various sources Pa , is connected to a second common valve stage, which is formed by the rectifiers BRCS and BRCP . This means that there are a total of 100/5 = 20 valves in the second stage, which in turn are divided into four groups of five each. The valves of each of these groups are successively connected to the five sources Pb 1 ... Pb 5. The valves corresponding to one of these groups are connected to a third valve stage CRCS and CRCP which is common to said group. Four valves CRCS and CRCP are thus provided, which are connected in succession to one of the sources Pci .. .Pc 4.

Each of the connections connected to a valve belonging to one of the sources Ρα ι ... Pa 5 is also connected to a second valve DRCP , which is connected to one of ten sources Pd 1 ... Pd 10 can be.

This connection identifies the group to which the connection belongs, in that a connection leading to source Pd 1, Pd 2 etc. means that the connection in question belongs to group No. 1, No. 2 etc.

It can be seen that the ground potential supplied via the P-wire is swallowed up in the resistor Rg at any time, since the potential of the lower end of this resistor is always kept at -40 V, except when the source connected to the respective valve to the connection in question Pd supplies a potential of -16 V, in which case the potential of the lower terminal of the resistor Rg is brought to this value of -16 V. In other words, the potential .of the lower end of Rg can be brought, that the grids of the intensifier tube is affected only in the period where the source of Pd sends a pulse, that is, for each of the terminals of group no. 1 at such a value during the time segments iao ι ... 120. Similarly, the connections belonging to the second group can only influence the grid potential in the time segments 121 ... 240, and so on.

This means that for each connection a pulse from the F wire can only be transmitted to the grid in one of the 1200 time segments,

which identify both the port number and the class to which said port belongs. For example, port no. 25 according to the table in FIG. 22 would send a pulse at time no. 31 depending on the sources Pa, Pb and Pc. If this terminal s belong together, for example, group no., So swallowed source Pd 5, the pulses transmitted by said terminal always out in the period corresponding to the fifth group of 120 time slots, so that under these circumstances a pulse only in the 31 period of the fifth period, ie in time segment No. 511 (ie No. 120 X 4 + 31;). The cathode of the amplifier tube SAV3 is normally connected to earth via a resistor GRS 1; the grid is then sufficiently negative to the cathode that about If the common control circuit is engaged, relay GB applies a potential of about -20 V via its normally open contact gb 3, because there is a circuit from the cathode of the suppressor tube SVA 4 to The cathode of SVA 3 is closed, the tube SVA 4 forming the right part of the double triode to which the amplifier tube SVAj belongs.

This suppressor tube is wired so that its cathode is normally -20V and its grid is -21.5V. Therefore the cathode of the amplifier tube SVA 3 comes to -20 V when the contact gb 3 is closed. Under these circumstances the potential relationships at the cathode and grid are such that the impulses transmitted by the valves do not in themselves affect the tube, but only have the purpose of charging a small capacitor GCi which connects the grid to a pulse source d 2 . The timing diagram of source d2 is also given in FIG. If this source sends a short positive pulse at a point in time when the capacitor is already charged by a pulse from the valves, the grid potential is temporarily raised so much that current flows in the anode circuit. A short pulse is transmitted to the anode circuit of the two triodes SVAI / SVA2 , which together form a further 'double triode and acts on these triodes via a transformer connected to said double triode in such a way that said triodes generate a pulse that is sent from their cathode circuit to the associated voter is transmitted.

As can be seen from FIG. 21, the beginning of this pulse coincides with that of pulse d 2, this coincidence occurring towards the end of that time segment which is allocated to the pulse generated by a particular terminal. The length of the pulse regenerated in this way corresponds to about half the length of a time segment, so that it still lasts for part of the next time segment. The short pulse is transmitted to the anode of the regenerator tubes and causes a current to flow in the primary winding of the transformer connected to said anodes. This has the effect that the potential induced in the secondary winding TS of the transformer makes the potential of the grids of the regenerator tubes more positive. When the amplitude of the applied potential is large enough to raise the grid potential to a suitable value, taking into account the grid bias, the generator is started. Anode current begins to flow through the winding TP of the transformer, the grids then become more positive and thus cause the anode current to increase again. The grid potential very quickly reaches a value which is above that of the cathodes; strong grid current begins to flow and thus limits any further increase in the grid potential. At this point the anode and grid currents begin to decrease, the latter decreasing more rapidly than the former, so that the difference between the ampere-turns of the anode and grid windings increases rapidly.

After a period of time, mostly from the self-induction of the transformer windings and depends on the anode resistance of the tubes, the grid current has become zero. Arranged from now on any further reduction in the anode current by induction will result in the appearance of negative voltage on the grid winding, which in turn causes a further decrease in the anode current. The tube quickly becomes non-conductive and remains in this state until a new trigger pulse arrives.

In this way the appearance of a pulse of almost rectangular shape comes about, its amplitude and duration neither depend on the amplitude nor on the shape of the triggering one Depend on the impulse.

It is clear that such a pulse is generated for each of the free connections and that all these pulses are transferred to the memory via the group selector in the following circuit: normally closed contact hmi, normally open contact ga6, normally closed contact HB 3 and the D wire.

The positive return pulses sent on the D wire are transmitted to the memory in the following way: D wire in the connection set (Fig. 9), normally open contact ccda2, D wire (Fig. 10) and in the memory (Fig. 12): D- Wire, contact D of the multiple selector RS, normally closed contact 0 ^ 4 and grid of the tube Va 1 (Fig. 14 and 15). The grid of the tube Va ι is normally strongly negative, because the resistance between the grid and the earth is 4 megohms, while the resistance between the 48 V battery and the grid is only ι megohms. Similarly, the grid of the double tube Vaz is normally negative, since there is always more than 500 kilograms of negative battery voltage on said grid. The device which stores the first digit in the memory transmits, in a well-known manner, Pd pulses in one of the ten time segments of the Pd cycle to the grid of the tube Va 2 via the normally closed contact so 3, normally closed contact fgz, normally closed contact fs 6, normally closed contact or 2 and normally open contact c / 12. Every pulse arriving at the grid of the tube Va 1

makes the tube conductive and the normally negative cathode becomes positive because of the high resistance in the cathode line compared to that of the anode-cathode line. Every time a pulse Pd is applied to the grid of Va 2, the tube becomes conductive and its cathode comes to positive potential.

In the case of two other double triodes Va ^ / Va 4, the cathodes are also connected via rectifiers Rc 3 and Rc 4, as are those of Vai / Va2; Said cathodes are parallel to the common wire which ends at the cathodes of Vai / Va2 and the grid of the tube Vo 2.

Ground potential is constantly applied to a tube Va 4 via the normally closed contact fs 4, so that said tube Va 4 is constantly conducting.

The grid of the tube VdJ is connected to the sources Pa <2 .... Pa6 via the normally closed contact ot4, normally closed contact si 5, normally closed contact fs 2 and the rectifiers connected to said sources. . During each of the pulses supplied by one of the sources Pa ¹ Z ... Pa 6, current flows from the negative central battery to the point with a potential of -16 V, which is obtained from one of the sources Pa 2 ... Pa 6 via the grid resistance of Va 3 and the rectifier corresponding to the source concerned is supplied; the grid comes to -16 V for the duration of the pulses Pa2 ... Pa6 and the tube Va 3 then becomes conductive. Meanwhile, for the duration of each pulse coming from source Pa 1, a potential of -40 V is applied to the grid of Va 3 and said tube then does not conduct. Negative potential thus prevails at the cathode of Va 3 for the duration of the pulses Pa 1, and the pulse generator is not actuated by the pulses coming from a common control circuit via the D wire during the duration of the pulses Pa 1.

Pulses from source d 3 are constantly transmitted to the grid of the tube Vo 2, resulting in a double ■. triode Voi / Vo2 , which is set up for pulse generation. If one or more of the cathodes Va i, Va 2, Va 3, Va 4 is negative, all pulses d 3 in a 20 kOhm resistor are swallowed up because a current flows through said 20 kOhm resistor, the rectifier Rc τ, Rc 2, Rc 3 or Rc 4 and the negative cathode or cathodes of the tubes, When pulses are sent to the grids of the tubes Va 1, Vaz, Fa 3! simultaneously through the group selector, the source Pd corresponding to the stored digit and the sources Pa2 .. .Pa6 are applied, all cathodes become positive at the same time, and the corresponding pulse d 3 makes the grid of Vo 2 positive, because no current flows through the 20 kOhm resistor and one of the rectifiers.

Hence, tube Vo 2 causes tube Vox to respond. Tube Voτ belongs to a pulse regenerator, which also has a transformer TPjTS , which lies between the anode and grid circuit, a resistor RRS and a varistor or thermistor TH parallel to the grid bias and cathode circuits.

As long as there is no trigger pulse, the grid of the tube Vo 1 is so strongly biased that the tube cannot work, and no current flows either in the winding of the transformer TO / TS or in the tube. If a negative potential is suddenly applied to the anode of the tube, this potential reverses its sign after being transferred to the grid winding of the intermediate transformer, and said grid then becomes positive. When the amplitude of the applied potential becomes large enough to bring the grid potential to a suitable value, taking into account the grid bias, the generator is started. Anode current begins to flow in the anode winding; the grid then becomes more positive and in turn causes a further increase in the anode current. Almost immediately the grid becomes more positive than the cathode; considerable grid current begins to flow, thus preventing any further increase in grid voltage. At this moment the anode and grid currents begin to decrease, the latter even more rapidly, so that the difference between the ampere-turns of the anode and grid windings increases rapidly.

After a period of time largely from self-induction the transformer windings and the resistance of the anode circuit of the tube depends, the grid current becomes zero. From this moment on, any further decrease in the Anode current the occurrence of negative potential in the grid winding, which in turn is another Causes decrease in anode current. The tube then quickly becomes non-conductive and remains in a state of rest, until a new trigger pulse arrives.

A current pulse of essentially right-angled shape is created in the cathode circle ',' its The amplitude and the duration are dependent neither on the amplitude nor on the shape of the triggering pulse.

The load resistor RRS, which is placed in the cathode circuit of the generator, makes it possible to convert the current pulse into a voltage pulse, said voltage being kept essentially at the same value for the entire duration of the pulse.

For every ^{triggering pulse applied to 1} the anode, a pulse is generated and the tube returns to rest. The voltage pulse arising at the ends of the cathode load resistor of Vo 1 is applied to the group selector via the rectifier Rcp and the C wire.

The pulse sent via the C wire also ignites the cold cathode tube Via, the cathode of which is at ■ -150 V; Relay Si is excited in the following circuit: cathode and anode of Via, normally closed contact ph ζ, relay Si ₃ normally closed contact ok6, normally open contact h 1, earth. The tubes Voa ... Fully extinguished 'do not ignite at' the observed moment because of the influence exerted on their control electrode by the valves.

Relay Ot is excited in the following current

circuit: normally closed contact on, normally closed contact es 5 , normally open contact s 14. As a result of the closing of contact ot 1, test relay T is connected to wire OA . The pulse transmitted again by the memory of the common control circuit is sent through the group selector in the following way: normally open contact lh 3, contact C of the multiple selector RS, C wire and in the connection set (Fig. 9 and 10), normally open contact ccda $, C- Core and in the group selector (Fig. 16), C-core, break contact HB 2, make contact ga-2. This pulse reaches a number of cold cathode tubes VRAi .. .VRAS, VRB ι ... VRB 5 and VRCi ... VRC 4, which are in the common control circuit; it arrives in the period following that when the pulse from the F-wire reaches tube SVA3. These 15 tubes are each controlled by a rectifier which is connected to one of the time pulse sources, the pulse diagram and tasks of which are shown in Fig. 21, so that said tubes can ignite only at very specific times. The tube VRAi is dependent on the pulse source Ra τ, the tube VRA 2 on the pulse source Ra2, etc., so that a tube like VRA ι can only ignite in one of the time periods when the source Ra 1 is transmitting a pulse, ie loud Fig. 21 in the time segments nos. I, 7, 13, etc.

Similarly, the tubes VRBi ... VRBs are each connected to one of the sources Rb ι ... Rb ζ via a rectifier, so that a tube, such as VRB i, can only ignite during one of the groups of time units where the source Rb ι is currently transmitting an impulse, i.e. in the time units ι ... 6, 31 ... 36, 61 ... 66 etc.

The tubes VRCi ... VRC 4 are also dependent on sources Rc 1 ... Rc 4 , the respective transmission times of which can be taken from FIG.

Finally there is a last tube Vd that does not depend on rectifiers and can therefore ignite every time it receives a pulse coming from the memory via the C-wire at any point in time.

It is clear from the above that a pulse arriving at any point in time will always ignite a tube in each of the three groups VRA, VRB and VRC and also the tube Vd ₁ so that a combination of tubes, one from each group, for is characteristic of each of the time periods.

For example, in the case of a pulse from port # 25 in group # 5, a pulse is generated in period number 511 (i.e., period 120X4 + 31) as previously indicated and it goes to the cold cathode tubes in the common control circuit in the time segment No. 512 a.

This pulse comes in at the moment when only the sources Ru 2, Rb 1 and Rc2 transmit a pulse; the tubes VRA2, VRBi and VRC 2 ignite and activate the relays Ab, Ba and Cb in the anode circuits.

Similarly, a pulse sent in period # 89, indicating port # 74 belonging to group # 1, is received by the cold cathode tubes in period # 90 where sources Ra 6, Rb 5 and Rc 3 are currently receiving a pulse hand over; the tubes VRA6, VRB 5 and VRC ^ ignite and cause the anode relays Af, Be and Cc to pick up.

The normally open contacts of the three anode relays that have picked up close circuits that control the Identify the connection to which the group dialer involved in the connection is to be connected.

It can be seen that the 50 time segments (1 to 60 and 61 to 120) used in each of the two rows are allocated to each of the two groups of 50 voter connections within a cycle of 120 time positions. Each of the two groups of 60 time units includes 6X5X2 combinations of the sources PaXPbXPc. If we consider the common control circuit, it is clear that the relays Ca ... Cd correspond to the four temporal positions of the cycle Pc , with Ca-Cb and Cc-Cd each being the two groups of 50 connections (00 to 49 and 50 to 99), while Ca, Cc and Cb, Cd each identify the two groups of 25 connections (00 to 24 and 50 to 74 or 25 to 49 and 75 to 99), which are connected by vertical electromagnets 1 to 25 and 26 to 50 can be controlled. The first group of connections (00 to 49) is connected through by a selection process on the part of one of the horizontal auxiliary magnets SHMA, the second connection group (50 to 99) by a selection process on the part of the other horizontal auxiliary magnet SHMB. The relays GD or GE respond when the relays Ca, Cb or Cc, Cd have picked up in order to control the selection of the selector. The table of Fig. 22 shows the numbers of the pulse sources Pa, Pb and Pc corresponding to the terminals. As already said, the sources of Ra, Rb and Rc are such uses in relation to the sources of Pa, Pb and Pc, that the designated by Nos. 25 in said table terminal ι by the pulse sources Pa 1, Pb and Pc2 in is, the sources Ra2, Rb ι and Rc 2 corresponds, so that the storage tubes VRA2, VRBi, VRC2 as well as the corresponding relays Ab, Ba and Ch for terminal 25 respond.

First, the circuit of one of the 50 vertical magnets VM of the multiple selector is closed; for connection no. 25 this circuit runs as follows: normally open contacts chi, from 6, ba-2 of the relays attracted by the tubes VRAz, VRBi and VRC 2 , vertical magnet no. 26; for connection no.74 this circuit is, for example, as follows: normally open contacts ccx, be ι, afs of the relays operated one after the other through the tubes VRA6, VRB 5 and VRC 3, vertical magnet no.25.

Thereafter, one of the relays GD or GB is energized as a result of the response of one of the relays Ca .. .Cd m series with one of the tubes VRC 1 ... VRC4. Therefore relay GD energizes depending on

one of the relays Ca or Cb via the contacts ca 2 or cb2, and relay GB is energized depending on one of the relays Cc or Cd via the contacts cc2 or cd2. The vertical magnet that has attracted "closes" the following holding circuit: Working contact vm i, which belongs to said magnet, working contact gd $ or ge 5, relay GH, earth. Relay GH interrupts the circuit of relay GB with its contact gh ι 25, the vertical bar No. 26 for a specific terminal 25 No .. call is actuated in the event and the vertical bar in the case of a number of terminal No. 74;. excited the perpendicular magnetic VM same time pushes the associated him vertical rod upward... These two rods control the ^{contacts leading to terminals 25 and 1} 75 and 24 and 74 respectively.

', Each of the vertical bars closes two pairs of contacts, ie contacts VB1 and VB 3 connected to those of the two terminals it controls (in group 00 to 49) and two other contacts VB 2 and VB 4 connected to belong together with the second connection.

One of the contacts closed in each pair is in series with the P ruf circuit to which the winding of relay GC belongs, so that this circuit is prepared by closing contact gd 3 of relay GD via one of the connection groups 00 bis 49 related contacts; Closing contact ge 3 of relay GB prepares a test circuit via one of the contacts in groups 50 to 99. This means that the selected connection can be checked using two possible circuits that only lead to the corresponding contact of the selected connection. In the case of a call for connection no. 25, the test circuit runs through gd 3 and contact VB 1, which corresponds to connection no. 25; in the case of a call for connection no. 74, this circuit runs through ge 3 and contact VB 2, which corresponds to connection no. 74.

Similarly, circuits are closed via the contacts gä \ and ge 4, which lead to the contacts of each pair belonging to the vertical rods, so that a second circuit peculiar to the selected connection can be made; the purpose of this circuit is given below.

As already indicated, the memory has the connection from. Relay T triggered with wire OA . Relay T then picks up in the following circuit: make contact ot-i, make contact It \ 2, make contact lh 9, contact OA of the multiple selector RS, wire OA and in the connection set (Fig. 10) make contact ccdai, Α wire (Fig. 9 and 16), normally closed contact HB 4, normally open contact ga8 in the group selector, relay GC in the common control circuit that is energized, normally open contact gd $ or ge 3, one of the normally open contacts VBi, VB 2, E-wire of the selected one of the vertical selection bars Connecting line; and battery. The closing of contact 1 1 closes the Doppelprüfstromkreis via the relay Dt and T in a well known manner, and provided that the connection in question has been elected only by the concerned Gespräichsverbindung, relay Dt likewise draws on. The contacts ot6 and dt 2 are now both open, which causes the drop in all of the activated line class relays Oa ... Oh . Contact dt 4th is closed and causes relay Cj to respond. Closing contact es 2 energizes relay Or, provided that all line class relays have de-energized as a result of the interruption of contacts of 6 and dt 3. Contact orl opens and causes relay Ot to drop out, which interrupts its normally open contact; Normally closed contact of 6 again puts earth to the relays and the tubes Oa., .Oh, Voa ... Voh, which mark the connections. The attraction of relay GC in the common control circuit causes the closure of a holding circuit for that one of the relays GD or GE that has picked up, so that this relay, as well as the actuated magnet VM controlled by GD or GE , no longer depends on the position of the anode relay Ca ... Cd is dependent. ■. .

As has been established, the return pulse from the memory causes the response of the tube Vd via the C-wire. Relay GF energizes in series with tube Vd; this relay shorts the winding of relay GB which slowly begins to drop out. Before relay GB can drop out completely, relay GC can pick up; Contact gc2> interrupts the circuit of relay GB, which now drops out immediately. At the fall Relay GB interrupts the contact gb 1, which in turn interrupts the anode circuit of all cold cathode tubes; those tubes that have ignited go out and cause the corresponding anode relay to drop out. The interruption of contact gb 3 does not put the tube SVA 3 out of operation, since contact ge 4 is closed.

After the identity of the selected connection has been determined, a test must first be carried out to determine the class of this connection. For this purpose, the second contact VB 3 or VB 4, which belongs to each of these connections, which can be reached via the working contacts belonging to the vertical rods, is switched through by flying connections with one of the 20 line class cores COL , depending on the class to which .the connection should belong.

These 20 wires COL are each connected via a high resistance COR to three successive valve stages which are controlled by pulse sources in such a way that the application of earth to one of these wires causes a pulse in a time segment that characterizes the connection point corresponding to this wire , with this impulse on the grating of an amplifier tube

VAz is given. The time interval at which this pulse is transmitted is given in the table in FIG. 18 for each of the 20 wires. It can be seen that all these time segments or temporal positions of the last time unit in each of the 20 successive groups to six time units Pa within-

half of a cycle of 120 time segments defined by the sources Pa, Pb and Pc. The first valve stage, which controls 20 line class cores COL , is always at source Pa6. These time segments are therefore the 20 time segments that do not belong together with the connections 00 to 99 according to the table in FIG. The second and third valve stages are dependent on sources Pb and Pc, and these are the same as those that cause the 100 test leads to be searched.

When relay GC has picked up, source Pa6 is also connected via a normally open contact gc 1 and a rectifier to the voltage divider OPT located on the grid circuit of the amplifier tube SVA3 ; this suppresses all those impulses that could arrive at different time units than those that correspond to the 20 connection classes.

Depending on the connection class, an earth connection is applied to one of the 20 line class cores via the contact that belongs to the vertical selector rod corresponding to the selected connection: pulses are transmitted to the amplifier tube SV A3 ^at the appropriate times, which is obtained in the working state that .the battery connection with the cathode via the normally open contact gcj. is maintained before contact gb ^ was able to break, so that the tube can respond under the action of the pulses received. These pulses are transmitted once in a cycle of 120 time units; the tube is triggered once in said cycle by the detection pulse supplied by source d2 , which is connected to the grid of tube SVA3 via a small capacitor GCi . This happens precisely at the moment when the pulse is sent by source d2 , which, as can be seen from FIG. 21, becomes effective precisely at the end of the time segment when a pulse comes from the wire COL.

This pulse is then regenerated by the method described previously for the dial pulses ¹ method. The regenerated pulse is then transmitted to the memory via the D-wire. In the memory, the flip of contact or 2 has disconnected the grid of Va 2 from the sources Pd in order to connect it to earth via a resistor of 50 kOhm while it is checked whether the line class relays Oa ... Oh have dropped out. This makes the cathode of tube Va2 positive, so that from that moment on the rectifier Rc 2 is not conducting and is unable to absorb the pulses from source c / 3 connected to the grid of tube Vo 2 . At the same time, the tube Va 3 is connected to the pulse source Pa 1 via the normally closed contact ot \ and the normally open contact si'3 as a result of the relay Ot dropping out. The sources Pa 2 ... Pa 6 are disconnected due to the interruption of contact si5. We now want to explain how the Va3 tube works. It can be seen that during the dialing period the grid of this tube is connected to the pulse sources Pa2 ... Pa6 via the break contact ot 4, the break contact si 5 and break contact fs2, each of the sources being connected via a rectifier to prevent mutual interference between to avoid the said sources. This means that as long as these sources of momentum are positive, so is Fa-3's grid; this tube, when it becomes conductive, causes a positive potential to be applied to its cathode; therefore the rectifier Rc 3 between the cathode of the said tube and the 20 kOhm resistor connected to the source d 3 is no longer conductive. As a result, during the time units when a selected pulse can arrive, the pulses from source d 3 cannot be swallowed up by rectifier Rc 3 , since tube Va3 and rectifier Rc3 have no influence on the dialing processes as described above. However, during the time corresponding to the emission of positive potential by the separated source Pa 1, the grid of the tube Va 3 becomes negative. Its cathode is brought to negative potential and the rectifier Rc 2 becomes conductive. This means that pulses which could arrive during the selection on the .D wire in the period corresponding to the transmission of positive potential by source Pa τ cannot become effective because the pulses d 3 arriving in the same time segment would be swallowed. The purpose of this measure is to prevent the memory from responding inappropriately to pulses which could arrive at times corresponding to the pulses from source Pa 1 during the dialing period. These pulses are used to provide the memory with an indication of the line class of the selected line, and a memory may only respond to pulses at one of the times that correspond to the working hours of the source Pa 1 , if it is also able to to include this information.

Let us now assume that the memory is in a state that allows it to receive information relating to the line class. The grid of the tube Va 3 is only connected to the source Pa 1, as indicated above, so that the rectifier Rc 2 then swallows all the pulses from the source d3 which correspond to the transmission of positive pulses by the sources Pa2 ... Pad. However, it does not swallow the impulses that correspond to the transmission periods of positive potential through the source Pa 1. The memory can therefore now respond to pulses arriving in one of the time segments which are reserved exclusively for pulses from the source Pa 1, and it is not influenced by pulses which could arrive at any other time segments. The grid of tube Va-J ₁ is still connected to earth and the corresponding rectifier is non-conductive.

If the pulse of the line class selected for the connection is applied to the D wire in a transmission period of the source Pa 1, the tubes Va ι and Va 3 are simultaneously conductive, and the tube Vo 2 receives a pulse. The pulse generator represented by tube Vo 1 generates a regenerated pulse which is contained in the

The moment begins when source dz is positive and is transferred to the C wire. This pulse has no effect on the common control circuit, since its contact gb ι is open, but it extends to the tubes Voa. ... VoH in memory. According to its temporal position, the pulse coincides with pulses Rb, Rc and Kai , which are applied via rectifiers to the resistors that belong to the control electrodes of a certain pair of tubes Voa ... ίο Voh ; in the case of a normal connection to a second group selector, it is the tubes Voa and Voe that respond and cause the relays Oa and Oe to pick up. In the case of a connection with a line selector , it is the tubes 1-5 Voa and V oh and the relays' Oa and Oh that respond.

Relay Ok is excited in the following circuit: normally closed contact 0 * 5, normally closed contact um3., Normally open contact dt 2, normally closed contact ph 6, normally open contact oh 4, normally open contact oai, earth.

The response of relays Oa and Oh causes relay Or to drop out through oa 3 and oh 3 , and relay Si falls.ab as a result of interruption of contact ok 6. The earth connection is removed from wire OB as a result of interruption of contact ok 5, so that the relay GA 'of the selector can be held via the magnet HM, contact g $ 4 and earth on the incoming E wire through contact ccda 5 (Fig. 9). As soon as the magnet HM has attracted, it opens its normally closed contact hm 2 and thus removes the earth from the J5 wire of the selector. Relay Ch remained temporarily attracted to the B wire at ok 5 after the earth dropped out as a result of the earth connection coming from the voter on the following path:, ß wire, in the connection set via fö4, magnet HM of the selector and contact hm 2, \ B-core; but now it falls off and thus results in complete control of the attraction of the selection magnet HM. ■

The ground connection created via the normally open contact dt 4, normally open contact Cii, normally closed contact chi, normally open contact 0/54 in the memory and the .D wire now causes the horizontal auxiliary magnet SHMA or SHMB to respond in the common control circuit of the selector, said magnet being controlled by the Response of one of the relays GD or GE was connected to the ZJ wire.

In the example of a call connection with connection no. 25, relay GD is energized; Magnet SHMA then picks up, while in the case of a connection with connection no. 74, relay GE is energized and magnet SHMB then picks up. This leads to the fact that the magnet SHMA pushes the horizontal bar of the individual selector to the left when it is attracted by which the horizontal magnet HM ^{had previously been excited -} as in the patent specification “Control and Compilation Devices for apparatus controlled by movable rods «; on the other hand, when the magnet SHMB is attracted, it pushes this rod to the right, so that in the first example the group selector is connected to connection no. 25 and in the second to connection no.

In the group selector, the contacts HB ι ... HB 4, which belong to the horizontal selector rod, completely separate the individual circuit of said selector from the common control circuit, and the test relays T and Dt in the memory return to the rest position. Relay Dt caused by dt4 the waste of relay Cs, and relay Ok drops due to breaking of the contacts dt 2 and 3, the ring pair in turn on the normally-closed contact ok 5 grounded, to energize relay FA in the occupied selector circuit, such as will be explained later.

When the five contacts A. ... E leading to the desired line are closed, the normally closed contacts HBi, HB 2, HB 3 and HB 4 open as a result of the displacement of the horizontal bars.

This brings the group voter into the desired speaking state and at the same time disconnects him the corresponding common control circuit.

The contact E of the selector closes before the normally closed contact HB 4, which is linked to the horizontal selector rod, opens. This puts earth on the Ε-wire of the connection via the normally open contact gay before the test circuit is interrupted, which keeps the connection occupied due to the short-circuit of the test potential applied to the £ -wire of the connection. This short circuit can also cause relay GC in the common control circuit and the test relays in the memory to drop before contact HB 4 is interrupted. The drop in the test relay connected to the yä wire in the memory causes the memory to cancel the earth connection that had been applied to the D wire in order to let the electromagnet SHMA or SHMB respond. It should be noted that magnet SHMA or, depending on the SHMB , a holding circuit has closed via earth, make contact shwiai or shtnb 1 belonging to magnet SHMA or SHMB , make contact gdz or ge2, depending on whether relay GD or GE has responded. Therefore, the horizontal auxiliary magnet does not drop immediately when the normally closed contact HBt in the group selector is interrupted. However, as stated earlier, relay GC is caused to drop out in the common control circuit, which in turn causes relay GD or GE to drop out. The vertical magnet VM falls again due to the dropping of said relay GD or GE, which causes the return of the actuated vertical selector rod to the rest position; the horizontal auxiliary magnet SHMA or SHMB also triggers because of the relay GD or GE. The relay GB in the common control circuit is now connected to the individual selector circuit via the normally closed contacts g-6'3 and gh χ ; the common control circuit is completely free and is now ready to set up a new connection.

It should be noted that the slope of the horizontal Auxiliary relay does not prevent the selector's horizontal selector rods from returning to the rest position

because they are kept in the attracted state by the group selector's own horizontal magnet HM.

In the application example described above the case has been considered where the voter had ioo connections and each of the ioo Connections were allotted ten time units. A potential pulse was applied to each of these ten units of time to identify the group,

ίο to which a connection belongs. Three more pulses of potential of different lengths identify a terminal and their coincidence provides a means of identifying that particular terminal. If we consider the 100 connections, the coincidence of the impulses assigned to them occurs one after the other within a cycle of 1000 time units. Provisions have been made so that the coincidence of these pulses one after the other in the connection between the selector and the memory control device actuates devices, which are normally electric valves, in such a way that a test circuit housed in said memory can search the electrical status of all connections one after the other. The storage controller searches for a port belonging to a particular group. When the pulse which marks the desired group has been recorded in the memory, the identity of the selected pulse, represented by its unit of time, is immediately reported to the voter and stored by a tube device located in said voter. The connection is then marked as busy. As was also communicated in the above description, the pulses marking the group are obtained from sources Pd ι .. .Pd το . The other three pulses, which identify the connection number in the contact banks of the multiple selector, come from the sources Pa 1 ... Pa5, Pb 1 ...

Pb 5, Pc 1 ... Pc 4. The coincidence of a particular combination of pulses Pa, Pb and Pc operated a device which is normally a valve, which is located between a particular terminal and the memory controller, so that the on-Ächluß thus is identified.

Of course, the 100 connections can be grouped in any way you want. The 100 can all be marked by pulses with a common temporal property so that they all belong to the same common group; they can thus all correspond to the same group of 100 time units identified by the source Pd 1 or by any other of the sources Pd 1 ... Pu! 10. According to another method, two ports can be assigned to the first group and three to the second group, while the remaining ports are assigned to the third group; In this case, the two first connections characterizing pulses are sent during the first 100 time units from the cycle of 1000 time units, while the next three connections characterizing pulses are transmitted during the second period of 100 time units and finally the pulses characterizing the 95 remaining connections sent during the third period of 100 time units. If there are a total of 1000 time units and 100 connections, it is possible to form up to ten connection groups, but the choice of a group to which a particular connection is to belong is in no way restricted. There can be any number of groups between 1 and 10, and the number of ports per group can be varied widely. It is thus possible to achieve a high degree of maneuverability, as the connections can be grouped according to the most diverse principles or assigned to a specific group. Although it is therefore necessary to have 1000 time units for 100 connections instead of the 100 time units required for simpler marking methods, the arrangement considered here does not mean a step backwards, but on the contrary offers unexpected advantages from the point of view of maneuverability and makes it easier to find the Identify connections.

We have already briefly underlined the fact that the distribution of the 100 connections over ten Groups has only been given as an example. It is not necessary to make the connections on a decimal basis to number, and, generally speaking, “connectors can stand alone or in any arbitrary Way to be considered divided into groups.

In the example under consideration, ten groups of ten connections have been formed, but one could just as well form five groups of 20 connections or four groups of 25 connections. It is possible to choose a special method of subdividing the η connections into groups, for example because it enables a better utilization of existing operating facilities, m test factors have been assigned to each of the η connections, however the connections may be distributed; as has been noted, said test factors consist of cycles of ten periods each, each of which corresponds to a source of potential pulses such as Pd 1. If we. create one of the test factors assigned to them for a certain number of connections, we thus form a defined group of connections among the totality of η connections of the selector. If we consider the second example mentioned, where three groups of connections consist of two or three or 95 connections, it can be seen that this result can be achieved by using m = three test factors Pd 1, Pd 2 and PdS by applying Pd 1 to the two connections of the first group, Pd 2 to the three connections of the second group and Pd 3 to the 95 connections of the third group. But as already stated iao, it is possible to add up to ten groups with ra = io. and, generally speaking, groups can occur in any number between 1 and m .

If we consider the circuit of the selector and that of the i * 5 Memory control device, as it is for a specific

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Application have been described, compare with the general case relating to η connections with m test factors (test criteria) each, so it is clear that 100 connections and ten test factors require 100 units of time, so that, generally speaking, a cycle of « -time η units of time must be present. For each of said time units, a circuit is formed between the connection on the selector and the test device of the ίο memory control device. It is possible to form m connection groups in the general case, while only ten can be formed in the case described. In order to enable the memory control device to select a connection belonging to a specific group, its test device contains a pulse source, such as e.g. B. PiZi, which sends pulses in time segments that identify the corresponding group. When a circuit is closed between a selector and the test device, the connection sends a pulse of the same time phase and the test device responds. Said device only responds to impulses of this type, while impulses coming from connections belonging to other groups have no effect. '

It should be noted that there are m groups at η time units for m possible line trunk groups. Each arrangement contains a time segment of its own for each connection, and the m time segments allocated for a connection are divided in such a way that one of these time segments is contained in a group of η time positions. The time periods of each group are to be identified by a common test factor, since two series of time periods never have the same test factor in common. In the example shown, the common test factors of the groups of 100 time units appear in different groups, each comprising 120 time units within a total cycle of 1200 time units. Each connection corresponds to ten time units which are individually allocated to it, one in each of the ten consecutive. There are rows of 120 time units in the cycle, and each port can be associated with one of the ten time units which can be individually assigned to it for grouping purposes.

It should be noted that the complete cycle consists of 1200 time units and that in each group of 120 time units) 20 are tangible. These additional time units are used to convey further information about the 100 lines, said information meeting the normal requirements of telephone exchanges. Provisions have thus been made so that at the time these additional signals are transmitted, the difference between the ten successive groups of 120 time units is not exploited, which makes it possible to form a cycle of 1200 time units; on the other hand, the cycle of 120 time units is used. If, of course, a larger number of additional signals were desired, the range could be expanded by adding not only Pd τ, but Pdτ and ¹ Pd 2 or the sources Pdι ... Pd 5 or at most all sources Pd τ ... Pd 10 would use. In these cases, additional signals 40 or 100 and 200 would be possible.

In the case of a central office, only 20 additional signals are used, with the said signals are used to indicate the line classes, such as B. that the relevant Line lies between two group dialers or between a group dialer and a line dialer. It can be seen that each of these additional Signals with multiple connections must be able to be related so that the Said signals are used in common for all connections and with each of these further signals one or more connections can be linked.

Precautions have been taken, two separate ones in succession by the storage control unit Call operations can be performed, the first being performed among the time slots that the port numbers are peculiar to a free port in the desired group choose while the second testing process takes place under the additional time units that go to the connections be allocated jointly.

It would be possible to have a common source with 1200 consecutive electrical, timed in to use pulses located in a certain way, but it is better to use different pulse cycles of different duration, but certain mutual temporal dependence to have each to establish the necessary test criteria for the various processes on site.

1200 test criteria, one for each connection ader connection class, must be made in the selector circuit itself by an electrical Going out steady state. To achieve this, a system of tubes is provided, the one Contains a series of electric valves that produce cycles of 1200 or 120 time units as required, of which 100 or, as the case may be, up to 20 time units can be used to constantly mark electrical states on the test wheels of connections or connection classes. It would be possible to do this through the To use a single stage with 1200 or 120 valves; but this method is expensive. It is more economical to provide several valve stages one behind the other. These valve stages are not even in decimal dialing systems necessarily on a decimal basis, so in the case 100 electrical states is possible to use three stages, one after the other five, five and four Instead of two stages, valves contain ten valves each. In fact, experience has shown that you can save material if you vary the arrangement of the valve stages.

In the example described, there are three or four different ones that are temporally located in a certain way

Pulse cycles have been used together to create cycles of 120 or 1200 time units.

Whatever the number of time units per cycle in the cycles used, the relationship between said cycles is always based on the principle of FIG. 21; In other words, there is a first cycle, which includes pulses, the duration of which is taken as a unit of time, and a second cycle, which includes pulses which individually each last as long as the entire first cycle together, and then a third Cycle with pulses each as long as the entire second cycle, etc. In the example shown there is no pause between the successive time segments of any complete cycle. However, in the case where pauses are provided, the duration of a pulse of the second cycle plus the corresponding pause would have to be chosen to be equal to the duration of the complete first cycle. In the example shown, the cycles Pa, Pb _1, Pc and Pd comprise six and five, four and ten timed pulses, respectively. There are thus six different series of pulses Pa , each comprising one pulse per cycle, but this pulse is at a different point in time for each of the series. There are five different series of pulses Pb .

Each of these different pulse cycles Pa appears once during the transmission of the different pulses Pa, five times during the transmission of the different pulses Pc, twenty times during the transmission of the different pulses Pd and two hundred times during the total of the ten pulse cycles Pd. Therefore, all cycles with six pulses Fa result in 200 X 6 = 1200 temporally different pulses in a complete cycle Pd or 20 X 6 pulses which are temporally different in a complete cycle Pc. Cycles of five individual pulses Pa in a complete cycle Pd are used to identify the time units of the connections, which gives 5 X 200 = 1000 individual time segments in a cycle of 1200 time segments. A 4-5 series of individual pulses Pa is provided in a complete cycle Pc to identify line classes, which gives 1 X 20 = 20 time units in a cycle of 120 time units. The various pulse cycles are used to control several valve stages which are arranged in the form of an inverted tree between the test wires of the connections or line classes and a common test device which, in the example described, is a feedback circuit that leads to the memory. The successive valve stages are controlled by sources Pd, Pa, Pb and Pc as shown in Fig. 18, each stage being controlled by sources of the same period.

With regard to the individual test criteria that indicate whether lines are free or occupied, the presence of a test criterion is used to indicate that the corresponding port free is. while its absence means that the port in question is busy. It goes without saying that the two relationships can be reversed.

It can be seen that the application of the individual criteria to the common test device is carried out Dormant electrical means are made that contain electrical valves. There are no moving parts provided in the devices that successively effect the test processes in the selector circuit.

It may happen that the same first dialing digit has to be used for two consecutive group dialing levels. In this case, the line class signal operates relays Oa and Og (Fig. 14). At the end of dialing with the finger washer, a relay in the memory responds in a well-known manner and causes the closure of the contact de ι in the circuit of relay Fg . Said relay is then excited in the following circuit: make contact de, break contact jo 2, make contact ok2 . Relay OM is energized when the double test process on a group selector is over and the two relays T and Dt have picked up. The contact fg $ separates .the Markierquellen Pd ι ... Pd 10 from the thousand digit and prepares the connection of the marking sources Pdi ... Pd 10 for the hundred digit. In the case under consideration, where the thousand digit in the next voter appears again as a hundred digit, the marking circuit is not closed for the selection by the hundred digit, but this is only the case when the relays Oa and Oe have picked up, i.e. when a second normal group voter has been occupied. If a group selector, for which the dialing is to be repeated with the thousands digit, has been seized, "ο causes the line class information given by said group selector to pick up the relays Oa and Og; therefore the marking circuit is closed again according to the selected thousand digit via the working contacts oa.4 and og 5 ·.

In the case where the relays Oa and Oe have picked up, the marking circuit for the thousand digit will not be closed, and the marking circuit through the hundreds digit would have been closed via the normally open contacts fg? ,, oa-2 and oe2.

If the connection selected by a group selector is a line selector, the line class signal causes the relays Oa and Oh to respond, and relay Fs picks up on the normally open contact fg2, normally closed contact foi, normally open contact oh 4 and normally open contact oaj. By moving contact fs6, relay Fs disconnects the marking line, which leads to the grid of tube Va 2 , from the marking lines of the thousands and hundreds and connects them via the normally closed contact ph 3 to one of the sources Pc, which is carried by the Tens have been chosen via the internal memory cross-connections; in the same period of time separates Contact fs 4, the grid of the tube Va ^ from earth to it or via the normally closed contact phi and break contact 3 with a

of the sources Pb , which has been selected via the internal memory cross-connections by the tens and units.

The grid of the tube Va 3 is connected to one of the sources Pa2 ... .Pa6 via the normally closed contact ot4, normally closed contact si S, normally open contact fs 2, normally closed contact ph6, which have also been selected by the units position by means of well-known arrangements made up of distributor frames is. The memory is now able to control the selection of a desired line by line selection circuits, as will be described. One notices that the line class relays that would have responded return to the rest position after the desired line has been selected; the interruption of the contacts oaj, oh 4. then enables relay Fs to build a holding circuit via the normally open contact fg2 ',. Normally open contact fsi and the relay FO, which is energized. The task of a line selector circuit is to select a subscriber line controlled by a memory in accordance with the tens and units of said subscriber number.

The circuit is based on the use of a multiple selector that has a certain number of horizontal Owns voting rods, each of which is viewed as the counterpart of a single voter who is able to mediate a conversation as well as a voter of the well-known Kind with movement in one direction only. 100 connections are provided, over all individual dialers are attainable. Vertical bars run across all horizontal bars and control the choice of a specific connection, which is carried out by means of the horizontal bar through a Single dialer should be connected.

A multi-selector of this type is used to service 100 subscriber lines and it exists from bucket certain number of individual Line voters.

Each such individual selector contains a so-called horizontal magnet, which belongs to the multiple selector, and a relay · FA.

A common control selector (see Figs. 7 and 8) is intended for all individual line selectors that serve a group of hundreds of lines. This circuit uses tubes and causes the actuation of a vertical and a horizontal selection rod of the multifunctional selector to to switch through a particular call connection depending on a memory that the Controls dialing processes by the line selector and according to the assignment of the desired connection. The operation of the line selector circuit is described at the same time as that of the common control circuit.

The dialing processes using the tens and units are not carried out separately; it will at the same time a single selection process is carried out depending on the tens and units of the Number of a desired subscriber in its entirety, as recorded in the memory and are stored in order to select a specific line from the 100 lines that can be reached via a multiple selector read out.

The dialing processes can therefore only begin when the desired subscriber number has been fully dialed.

Precautions' have been taken in the common control circuit of the line selector so that each line can be assigned a class information selected from several possible information through flying connections. The common control circuit is so arranged that it transmits this criterion memory which builds up the conversation, in such a way that ¹ the latter, if necessary, modify the operations when the connection of the routing class corresponding to or can be omitted can.

Two different methods are available to make connections to hunt groups to deal with these two approaches separately or in any appropriate way Combination can be used.

It will now be explained how connections with. Hunt groups are treated. First Each group of roo lines can contain any number of small groups (hunt groups), each of the lines of said groups having subscriber numbers in direct numerical order, am best within the same decade, i.e. H. Numbers with the same tens.

The common hunt group number for such groups is the number of the group's line with the lowest number. The remaining lines of the hunt group can each with themselves their own number. When busy initiates the selection of each line of such a hunt group, with the exception of the last one, Free choice among the other heads of the group.

This is interesting when using a large number of small hunt groups, each one consist of two to three trunk lines and evenly across all hundreds of lines are distributed in order to make the traffic evenly.

Second, there can be a limited number of hunt groups in each of the hundreds of lines are formed by any combination of lines united in a group. So it is possible, for example, with the in the common control circuit to form a total of six hunt groups of this type. the Common collective number which, when busy, can be dialed freely from the other lines in the group initiated, any line in the hunt group can «a; in other words, this common number does not necessarily need to be the lowest or highest number below the lines of the hunt group. The other lines in the group can each be used for to be called with their own number; but they do not initiate a free election when occupied. This possibility is of interest if a

Single line is to be extended to a hunt group or if the number of lines in a group of the first mentioned kind is to be increased in the special case where there are no lines more are available that would allow a group of lines in direct To form or expand a sequence of numbers, but where it is possible to use other lines within the relevant Pull up a group of hundreds and

ίο if at the same time it is desirable, such Lines can be reached by dialing freely without the call number of the existing line or the hunt group to change.

If the line selector has been occupied by the group selector, relay FA is excited in the said line selector in the following circuit: earth, normally closed contact okc, in memory (Fig. 12), normally closed contact et 3, work contact It 4, normally open contact lh 10, contact OB in the multiple selector RS, wire OB and in the connection set (Fig. 9 and 10) normally open contact ccdaä ,, B-wire through the group selector (Fig. 16) and in the line selector (Fig. 19) normally closed contact hm 2 on the horizontal magnet HM ₁ relay FA, Battery; the earth of contact ok $ (Fig. 12) also causes relay Ch in the memory to pick up.

Pulling in relay FA connects the line selector circuit directly to the corresponding common control circuit by connecting wires A ₁ C and D to the common control circuit via the normally open contacts fa $, fa.2 and fa6.

Furthermore, relay FA builds a holding circuit via the £ wires in series with the winding of the horizontal magnet HM and the normally open contact fa 4; but the magnet HM cannot attract at this particular moment because earth is directly at both ends of its winding. The Ε-wire is actually connected directly to earth via the make contact gay belonging to the group selector (Fig. 16).

The common control circuit comes into the working state by earth of said common control circuit being transmitted via the following path: normally closed contact HBt, the horizontal selector bar, normally open contact fai, normally closed contact Ifsh i, normally closed contact If se 3. This earth connection energizes relay LFSB in series with the after resistance to the battery. Via its contact Ifsb ι relay LFSB puts earth to the anodes of the cold cathode tubesLRST.-i, LFSVB, LFSVC ₁ LFSVD; Via its contact Ifsb 4 , it applies a potential of - 150 V to the cathode of the left-hand system SVAt, a double triode SVA3 / SVA4, and thus prepares the common control circuit for the selection of the line sought by the line selector ^.

A 100 kOhm resistor i? G- is located in the common control circuit for each of the 100 lines accessible to a group of line selectors; one end of said resistor is connected to one of 100 connection points which are connected to seven electrical pulse sources Pd 4 ... Pd 10 as desired. There is a connection point for each line.

The other end of the resistor Rg is connected via a rectifier Res to three successive rectifier stages ARCS ₁ BRCS and CRCS and rectifiers ARCP ... CRCP in the branch and leads from there to a potential of -40 V at a voltage divider OPT in the common control circuit ; this potential is applied to the grid of an amplifier tube SVA3 / SVA4 via a high resistance ORH . The rectifiers ARCP ... CRCP located in the shunt branch are connected to the current sources already described.

Let it now be assumed that the resistor Rg (Fig. 8) is connected to Pd4 ... Pd 10 and that said source has a potential of -16 volts. No current can then flow from this source to the voltage conductor OPT and from there to the grid of the tube SVA 3, unless this potential of -16 V is applied simultaneously to all three rectifiers ARCP, BRCP and CRCP which are connected to the search circuit. If, on the other hand, the potential supplied by the three sources, or even just one of them, is -40 V, while the potential at Rg is -16 V, then in reality -40 V is applied to the circuit containing the resistor Rg in the common control circuit of the line selector with the voltage divider OPT connects, because said -40-V potential can be through a rectifier in the shunt branch, such as. B. ARCP, come in because in this case it is low resistance; the potential difference between the lower end of Rg and the pulse source connected to the rectifier located in the shunt arm is swallowed up in the resistor Rg , and no current flows on the voltage divider. The rectifiers in the shunt branch act as valves that may or may not make the circuit ending in the voltage divider OPT permeable. Current can only flow to the voltage divider if the valve device is made permeable by applying -16 V from the pulse sources involved. It is clear from this that current flows from one of the sources Pd to the voltage divider only when all of the valves relevant to the circuit that connects the resistor Rg of a certain line to the common voltage divider OPT are simultaneously permeable. Therefore, it is only at this moment that the voltage of the voltage divider and consequently that of the tube SVA 3 is brought to about -16 V as a result of the resistance ratios in the various resistors in the circuit.

It can now be seen that the three series of sources Pa, Pb and Pc are connected to the valves in such a way that the moment at which these three valves are permeable is different for each of the 100 lines; each of the lines therefore supplies the grid of the tube SVA 3 with a pulse in a single period of time which characterizes the line in question. The procedure, like that

various valves are connected so that this result can be achieved for the various ports numbered from oo to 99 is shown in FIG. 22; this figure also shows the respective time segment in which each of the connections transmits its -Impute. It should be noted that this table lists time segments numbered 1 to 120, taking precautions so that the sixth segment of each group is not used for pulse transmission, using only 100 of the 120 pulses for the 100 lines. Each connection point of a cable switch is connected in the common control circuit (Fig. 8) to an individual rectifier ARCP, which is connected to one of the sources Pa 1 ... Pa 5. Each group of five of connections, each of which is connected to a different source Pa , belongs to a common second stage, which consists of the valve BRCS and BRCP ; there are therefore a total of 20 valves in the second stage, which in turn are divided into four groups of five. In each group of the second stage, the five valves are each connected to one of the five different sources Pb 1 ... Pb 5. The valves of a group are now connected to a third stage of valves, which consists of the rectifiers CRCS and CRCP ; four valves like the above are provided, each with one of the sources Pci . ... Pc 4 is connected. As noted, each of the lines is initially connected to its own rectifier, which is connected to one of the sources Pa 1 ... Pa 5; but it is also connected to one of the sources Pd ^ .. .Pd 10 via the rectifier Res, resistor Rg and an on-the-fly connection.

This connection identifies the line class. to which the respective line belongs; a connection to a specific source Pd shows, for example, that said line is a single line or that it is the first line of a hunt group.

It is clear that the potential of -16 V supplied by the line-connected source Pd is swallowed up in the resistor Rg and that the potential at the upper end of this resistor remains at -40 V, unless the sources Pa, Pb and Pc , to which the respective test wire is connected, just deliver a potential of -16 V. Therefore, for each individual line of class no. 4, the potential at the upper end of Rg must be brought to a value which can affect the grid of · SVA 3 in the time when the source Fd 4 is relatively positive, ie in the Periods of time Nos. 361 to 480. Similarly, a line or lines connected to Pd 5, for example a first line of a collective connection, can only affect the potential of the grid in periods of time Nos. 481 to 600.

From the above, it is clear that for each individual line a pulse of - 16 V is applied to the grid of the SVA3 tube in only one of the time units and thus identifies the line in question.

For example, according to the table in FIG. 22, line 25 sends a pulse in time segment 6g no. 31 depending on sources Pa 1, Pb 1 and Pc 2. If this line is connected to source Pd 5, for example, this source suppresses the pulses everywhere except in the fifth period of 120 time periods, so that under these circumstances a lump pulse only occurs in the 3-1. Period of the fifth period, i.e. h, in period no. 511, is transmitted.

The cathode of the amplifier tube SVA 3 is normally connected to earth via a resistor GRS '; the grid is then sufficiently negatively biased against the cathode that the pulses arriving via the valves do not ignite the tube. When the common control circuit is occupied, relay LFSB applies a potential of about -20 V to the cathode of SVA% via its normally open contact Ifsb 4 because a circuit is closed from the cathode of a suppressor tube SVA4 to the cathode of SVA 2i . Tube SVA 4 is the triode on the right in the double triode to which the amplifier tube SVA 3 belongs. The suppressor tube is connected so that its cathode is normally at about 20 volts because its grid is normally held at -21.5 volts. Therefore, if contact Ifsb 4 is closed, the cathode of the amplifier tube SVAz is also brought to -20 V. Under these circumstances the potential relationships at the cathode and grid are such that the impulses coming from the valves cannot actually affect the tube by themselves; they only have the purpose of charging a small capacitor GCi that directly connects the grid with the pulse source. d \ 2 , the timing diagram of which is also shown in FIG. When this pulse source rf 2 transmits a short pulse in a moment where the capacitor is anyway through one of the. Valves coming pulse is charged, the grid potential is momentarily increased so much that current begins to flow in the anode circuit. A short pulse is then transmitted to the anode circuit of the two triodes SVA1 / SVA2 that form the other double triode, and it acts on these triodes via a transformer belonging to said double triode in such a way that said triodes generate a pulse that no from their cathode circuit the associated line selector circuit is transmitted. This pulse thus begins at the same time as pulse d 2, ie towards the end of the time segment when a pulse is sent out by a specific line, as can be seen in FIG. The duration of the regenerated pulse is approximately equal to a time segment of the source Pa, so that it always continues during the next time segment where the said source Pa emits a pulse. iao

Since the individual lines are connected to the pulse source Pd 4 , it is clear that all tangible individual lines send a pulse within the time units 361 ... 480. All these pulses are transmitted via the line selector of the memory circuit via the normally closed contact hm 1,

Normally open contact fa 6, normally closed contact HB ι and the P wire to the memory.

The pulses coming back on the D wire reach the grid of the electron tube Va ι (Fig. 15) via the normally closed contact ofe'4. Normally the grid of Va 1 is strongly negative because the resistance between positive earth and the grid is 4 megohms while that between the negative battery of 48V and the grid is only 1 megohm. The grid of the double tube I'a 2 and that of each of the two other double tubes F03, Va4 are also strongly negative, because they are constantly above 500 kOhm on a negative battery.

It is assumed that the memory controller has stored the two digits on a decimal basis in a well known manner and that said digits have been somehow converted to bases 4-5-6 as required for control of choice in a system such as the one contemplated was. The conversion means that are present can be of a well-known type, as have been customary in memory control devices for years. Switching means, such as telephone-type low-voltage electromagnetic relays, then connect a source of each of the series Pc, Pb and Pa according to the conversion just made; the said sources are each connected via the following current paths:

Break contact ph 3, make contact fs 6, break contact or 2, make contact cli2 and grid of tube Va 2, further break contact or 3, break contact ph 1, make contact fs 4 and grid of tube Va 4 and finally break contact ph 6, make contact fs 2, break contact si 5, normally closed contact 0 * 4 and grid of tube Va 3.

The circuit arrangements described above have been more common for years Circuit technology provided and therefore fall within the knowledge of every circuit engineer; we are therefore of the opinion that a supply of detailed current flows and the Explanation of such arrangements only uselessly prolong the present patent description and the Invention itself would necessarily make it less clear.

Every pulse arriving at the grids makes the corresponding tube conductive, and that normally negative cathode becomes positive in view of the high resistance of the cathode path in comparison with that of the anode-cathode line.

In both double triodes Va 1, Va2 and F03, Va4 , the cathodes are mutually connected via the rectifiers Rc τ, Rc2, RcS, Rc4 , and they are all parallel to the grid of the tube Vo 2 via a wire common to all cathodes.

If an impulse is received on a grid, current flows from the central battery to the Pulse source with -16 V across the grid resistance; the grid comes to -16 V for the duration of the said impulses; the corresponding tube then becomes conductive. At all other times -40 V reach the grid of the corresponding tube, and the said tube is then blocked.

Pulses from a source d ^ are regularly applied to the grid of a tube Vo 2 which belongs to a double triode Vo i / V02 connected for pulse generation. As long as one or more of the cathodes of the tubes Vai, Va2, VaJ,. And Va4 are negative, every pulse d-3 in the 20 kOhm resistor is swallowed up because current flows through said resistor, one or more of the rectifiers Rc 1, Rc 2, Rc ^ and Rc 4 and the negative cathode and cathodes, respectively. If, however, pulses are applied to the grids of the tubes Va 1, Va 2, Va 3, Va 4 simultaneously by the line selector and by the sources Pc, Pb, Pa, which are selected on the basis of stored dialing digits, then all cathodes become positive at the same time, and the corresponding pulse d $ makes the grid of Vo 2 positive, since no current flows through the 20 kOhm resistor and one of the rectifiers.

Therefore tube Vo2 energizes tube Vo 1. Tube Vo 1 is part of a pulse regeneration circuit which also includes a transformer TP / TS between the anode and grid circuits, a resistor RRS and a varistor or thermistor TH between the grid bias and cathode circuits.

As long as no trigger pulse occurs, the grid of the generator tube Vo 1 is so strongly pretensioned that said tube cannot respond, and no current flows through the windings TP / TS of the transformer and the tube. If a negative voltage is suddenly applied to the anode of the tube, this voltage changes sign after it has been induced in the grid winding of the intermediate transformer, and the grid becomes positive. When the amplitude of the applied voltage is large enough to raise the grid voltage to a value which, taking into account the grid bias, enables the tube to respond, the generator is triggered, anode current begins to flow through the anode winding, and the grid potential is therefore increased more positive and in turn causes a renewed increase in the anode current. Thus the grid potential rises almost immediately above that of the cathode; fairly strong grid current begins to flow, which prevents any further increase in grid tension. At this moment the anode and grid currents begin to decrease, the latter more rapidly than the first, so that the difference in the ampere-turns in the anode and grid circuit becomes greater and greater.

After a period of time, mostly from the self-induction of the transformer windings and depends on the anode resistance of the tube, the grid current becomes zero. From that moment on every decrease in the anode current causes negative voltage on the grid winding, which in turn caused a further decrease in the anode current. Thus, the tube is quickly blocked and remains in the idle state until a fresh trigger pulse is received. In this way arises in the cathode circle a current pulse of essentially rectangular shape, with amplitude and time

duration of the said pulse neither on the amplitude still depend on the shape of the triggering impulse.

The load resistor connected to the cathode circuit of the generator tube converts the current pulse into a voltage pulse; said voltage is kept at a practically constant value over the entire pulse duration due to the presence of the thermistor. ίο. For each trigger pulse applied to the anode, a new pulse is created. The voltage pulse arising at the ends of the load resistor from Vo ι reaches the line selector via the rectifier Rcp and the C wire. tS The pulse sent via the C wire also triggers the cold cathode tube Via, the cathode of which is at -150 V, which triggers the response of relay Si in the following circuit: cathode and anode of tube Via, normally closed contact ph 5, relay Ä, Normally closed contact ok 6, normally open contact bl, earth. The tubes Vabu, Voa ... Voh, which are blocked, do not ignite at the moment in question because of the control exerted on their control electrode by the associated rectifier sets. Relay Ot is excited in the following circuit: normally closed contact or 1, normally closed contact es 5, normally open contact si 4 .; the closing of contact ot-i causes a connection of the test relay T with wire OA.

. The pulse is passed on from the memory to the common control circuit in the following circuit: C-wire (Fig. 19), normally closed contact HB 2 in the line selector, normally open contact fa 2 and cold cathode tubes LFSVA1 .. .LFSVA 6,, LFSVB τ .. . LFSVB 5, LFSVC ι ... LFSVC 4; it arrives in the period following that when the tube SVAz has received an impulse. . These 15 tubes are each controlled by a valve which is connected to one of the time pulse sources, the diagram and tasks of which are shown in FIGS. 21 and 22, said tubes being able to ignite only at very specific times.

For example, the LFSVA 1 tube is controlled by the pulse source Ra 1, the LFSVA 2 tube by the pulse source Ra2, etc., so that a tube like LFSVAi can only ignite in one of the time periods when the source Ra 1 is relatively at positive potential is, that is, according to Fig. 21 in the time segments nos. i, 7, 13, etc.

Correspondingly, the tubes LFSVB1 ... LFSVB 5 are each connected to one of the sources Rb 1 via a valve. ..Rb $ connected so that a tube "like LFSVBi can only ignite in one of the time segments where the source Rb 1 is relatively speaking at positive potential, ie in the time segments No. ι to 5, 31 to 36, 61 to 66 etc. Similarly, the tubes LFSVCf. Ll ⁷ SFC 4 are controlled by the sources Rc τ ... Rcq. , the pulse transmission times of which can also be taken from FIG.

Finally there is an LPSVD tube; which is not dependent on valves and therefore ignites every time it receives a pulse from the memory via the C-wire at any point in time.

It is clear from the foregoing that a pulse arriving at any point in time will always cause the ignition of a tube in each of the three groups LFSVA, LFSVB and LFSVC , so that a combination of three tubes from each of the three groups marks each of the time periods.

For example, in the case of a pulse from terminal no. 25 during an instant when source Pd 5 is operating, a pulse arises in period no. 511, ie in period 120 X 4+ 31, as already explained, and it comes from the cathode tubes common control circuit in time segment no. 512.

This pulse is received in a time segment where only the sources Ra2, Rb 1 and Rc 2 are at a relatively positive potential, so that the tubes LFSVA2, LFSVBi and LFSVC2 ignite and cause their anode relays LPSAB, LFSBA and LFSCB to respond.

It can be seen that each of the two groups of selector terminals corresponds to 60 time units of the cycle of 120 time units. Each of the two series of 60 time units comprises 6X5X2 combinations of the sources Pa, Pb and Pc. If we consider the common control circuit , it can be seen that the relays LFSCA ... LFSCD correspond to the four time segments Pc , with LFSCA, LFSCB or LFSCC, LFSCD each being the two groups of fifties from connections 00 to 49, 50 to 74 and 25 to 49, 75 to 99, which are dependent on the vertical magnets 1 to 25 and 26 to 50. The first connection group is switched on by a selection process on the part of one of the horizontal auxiliary magnets LFSHMA, the second connection group by a selection operation on the part of the other horizontal auxiliary magnet LFSHMB. The relays LFSD or LFSE are actuated to control the dialing processes depending on the relays LFSCA, LFSCB and the relays LFSCC and LFSCD .

If we look at the table (Fig. 22), we find the pulse sources Pa, Pb and Pc associated with each of the connections. As has already been said, the sources Ra, Rb and Rc are used in connection with the sources Pa, Pb and Pc in such a way that connection no. 25, which corresponds to the sources Pa 1, Pb 1 and Pc 2 in said table , also corresponds to sources Ra 2, Rb ι and Rc 2 , the storage tubes LFSVA 2, LFSVB 1 "5 and LFSVC2 and the associated relays LFSAB, LFSBA and LFSCB for connection no. 25 then attracting. This corresponds to the contact combination that it 8, contacts Ifsab6, Ifsbaz and Ifscbi cause perpendicular magnet LFVM No. 26. Similarly, for terminal No. 74, sources Ra 6, Rb 5 and Rc 3 cause the Excitation of the relays LFSAF, LFSBE, LFSCC, and magnet LFSVM No. 25 is excited via the contacts Ifsaf 5, Ifsbe 1 and Ifsee 1,

First there is a circuit for one of the vertical magnets LFVM; For example, this circuit for connection no.25 runs as follows: normally open contact of the relays LFSAB, LFSBA and LFSCB, which have attracted LFSVA 2, LFSVBi and LFSVC 2 as a result of the tubes, and the vertical magnet no.26.

Then one of the relays LFSD or LFSE picks up , as a result of the response of one of the relays LFSCA ... LFSCD in series with one of the tubes LFSVC ϊ ... LFSVC4; Relay LFSD picks up depending on one of the relays LFSCA or LFSCB via contact lfsca, 2 or Ifscb 2 ; Relay LFSE picks up depending on one of the relays LFSCC or LFSCD via contacts Ifsee 2 or lfscd, 2. The vertical magnet that has attracted forms a holding circuit via its own make contact Ifvm 1, one of the make contacts Ifsd 5 or Ifse 5, relay LFSH and earth.

Relay LFSH interrupts the circuit of relay LFSB via normally closed contact Ifshi.

At the same time, the vertical magnet LFVM, which has been energized, pushes the associated vertical selector rod upwards; the vertical selection stick no. 26 is operated in the case of a call for connection no. 25 and the vertical selection stick no. 25 in the case of connection no. 24 and 74 are connected.

A circuit is closed by one of the contacts Ifsds or Ifse 3 to one of the contacts belonging to each actuated selector rod, so that a special connection can be made according to the selected connection.

As has already been noted, the memory circuit has caused the test relay T to be connected to wire OA. Relay T is then excited in the following circuit: earth, relay T , normally open contact oti and the already described current flow up to the ^ i wire in the line selector (Fig. 19), normally closed contact HB4, normally open contact / 05, relay LFSC in the common control circuit, Resistor 240 ohms, battery. Relay LFSC picks up .

Closing contact ii creates a test circuit. Double assignment via the relays Dt and T according to the well-known method; Relay Dt also picks up, provided that the line in question has only been controlled by the memory control device in question. The contacts ot 6 and dt 3 are both kept open, so that all line class relays Oa ... Oh , which had picked up, drop out. Contact dt4 is closed and energizes relay Cs. Closing contact cf 2 causes relay Or to be energized, provided that all line class relays Oa. . ■. Oh as a result of the interruption of the contacts of 6 and dt 2 have returned to the rest position. Contact or ι is opened and brings relay Ot and ¹ the

Go associated contacts in the rest position, so that again earth is applied to the relays and line class tubes Oa ... Oh, Voa ... Voh . The response of relay LFSC in the common control circuit closes a holding circuit for that one of the relays LFSD or LFSE that has picked up , so that this relay like the magnet LFVM, which has picked up and is dependent on LFSD or LFSE, depends on the position of the anode relay LFSCA ... making LFSCD independent.

As noted, the return pulse transmitted from the memory via the C-core triggered the LFSVD tube. Relay LFSF energizes in series with tube LFSVD and short-circuits the winding of relay LFSB, so that said relay slowly begins to drop out. Before relay LFSB can completely drop out, relay LFSC can pick up , so that the circuit of relay LFSB is interrupted by the normally closed contact Ifse 3 and LFSB drops out immediately. When it drops out , it opens the contact Ifsb 1, which in turn interrupts the anode circuit of all cold cathode tubes, so that those of the tubes that had ignited go out and their corresponding anode relays drop out. The interruption of contact Ifsb 4 does not put tube SVA 3 out of operation, since contact Ifse4 is closed.

After the identity of the selected line has been determined in this way, something further is done to determine the line class; For this purpose, the normally open contacts LFVBi and LFVB 2 belonging to the vertical contacts are through-connected for each of the lines by flying connections to one of the 20 line class cores COL, depending on the class to which the connection belongs.

These 20 wires COL are each connected via a high resistance COR to three successive valve stages which are dependent on pulse sources, so that the application of earth to one of these wires causes a pulse in a time segment that corresponds to said wire and said pulse to the grid the amplifier tube SVAz is transmitted. The time period in which this pulse is transmitted is given for each of the 20 wires in the table (Fig. 8). It can be seen that all of these time segments correspond to the last time segment in each of the 20 successive groups Pa of six time segments each, within a group of 20 time segments which is defined by the sources Pa, Pb and Pc . The first valve stage, which controls the COL wires of the 20 line classes, is always at source Pa 6. There are thus 20 time segments which, according to the table in FIG. 22, do not belong to connections 00 ... 99. The second and third valve stages are controlled by sources Pb and Pc, and these are the same as those that cause the 100 test wheels to be searched.

When relay LFSC has picked up , the source Pa 6 is also connected to the voltage divider OPT via the normally open contact Ifse 1 and a rectifier; under these circumstances all impulses are suppressed which may arrive at times other than those which correspond to the 20 line classes.

Therefore, according to the line class, earth is connected to one of the 20 line class cores via the

Contact of the vertical dial corresponding to the selected line; Pulses are transmitted in the time segment which corresponds to the amplifier tube SVA 3, which is obtained in the working state in that a battery is connected to its cathode via the working contact ifsc-4 before contact Ifsb 4 was able to break, so that said tube is then able to respond to the impulses. These pulses are transmitted once every cycle of 120 periods of time by a detection pulse emitted by the source dz, the source being connected to the grid of the SVA 3 tube via a small capacitor GC 1. This happens exactly at the point in time when the pulse is emitted by source d 2 , ie exactly at the end of the time segment when a pulse is delivered via the wire COL .

This pulse is then after that for the dialing pulses described method regenerated.

The regenerated pulse is then transmitted to the memory via the D wire. In the memory, the switching of contacts or 2 and or 3 when checking for a drop in the line class

relais Oa Oh the grids of the tubes Va 2, V & 4

separated from the sources Pc and Pb and instead connected to earth via a resistor of 50 kOhm. Therefore the cathode of the tubes Va 2 and Va 4 is positive, so that from this moment onwards. the rectifiers Rc 2 and Rc 4 do not conduct and cannot swallow the pulses from the pulse source dz connected to the grid circle of the tube Vo2. At the same moment, the tube Va 3 is connected to the source of the irripulse Pa 1 via the normally closed contact ot ^ and the normally open contact si 3 because of the drop in relay Ot . The rectifier .Rc 3 therefore now swallows all of the pulses coming from the source α "3 which correspond to the transmission times of the sources Pa 2 to Pa 6. But it does not swallow those pulses which correspond to the transmission times of the source Pa 1 be influenced by the pulses arriving in one of the time segments which correspond exclusively to the transmission periods of Pa 1, while it does not respond to any other pulses which might arrive at times which correspond to the voter control.

It can be seen that during the selection of the line a first differentiation according to line classes was made by one of the various sources Pd Tor, but a second differentiation according to line classes is now carried out by the various combinations of Pb and Pc in a second series of processes. The purpose of these two distinct distinctions will become apparent below.

If the δα pulse corresponding to the selected class is applied to the D wire in a period of time when the source Pm is working, the tubes Va τ and Va 3 become conductive at the same time, and a pulse is transmitted to the tube: Ko2. The pulse generator consisting of tube Vo 1 then generates a regenerated pulse which begins the moment the source (23 is positive, this pulse being transmitted on the C-wire. This pulse has no effect on the common control circuit of the line selector , since their contact Ifsb-x is broken, but it arrives at the tubes Voa ... Voh in the memory. According to the time period in which the said pulse is received, it coincides with the pulses Rb ₃ Rc and Ra 1 , which are generated via rectifiers the resistances of the control electrodes of a certain pair of tubes Voa ... Voh are applied In the case of a connection with a single line, the tubes Voa and Voe ignite, causing the relays Oa and Oe to pick up, and the corresponding relays pick up.

Relay Ok is then excited via the normally closed contact ot 5, normally closed contact buz, normally open contact dt2, normally closed contact ph 6, normally open contact oe 4 and normally open contact σαι.

The response of the relays Oa and Oe causes relay Or to drop out due to the interruption of contacts σα 3 and oe 3, and relay Si drops out due to the interruption of contact ok6. The interruption of contact ok 5 removes the earth from the B wire, so that relay FA in the line selector builds the following holding circuit: Magnet HM, normally open contact / # 4 and incoming wire JS to earth. As soon as the magnet has attracted HM , it interrupts its normally closed contact / mm 2 and thus removes the earth from the J5 wire of the line selector. Relay CH had been temporarily moved to the discontinuation of the earth with ok 5 off I Vein by coming from voters earth via said £ Vein, break contact hm 2, magnetic HM, normally open / Ό4, peR wire and ground?; now it falls off and thus ensures that the magnet HM and the line selector have completed their tasks.

The earth via the normally open contact dt 4, normally open contact cii, normally closed contact chi, normally open contact ok4 in the memory and the D wire now causes the horizontal auxiliary magnet LPSHMA or LFSHMB to be excited in the common control circuit of the line selector, which is activated as a result of one of the relays LFSD or LFSE responding the D wire is connected. The horizontal auxiliary magnet actuates the horizontal selector rod.

When the magnet LFSHMA has attracted, the horizontal rod of the line selector, in which the horizontal magnet HM had already attracted, is shifted in a certain direction, for example to the left, while when the magnet LFSHMB has attracted, the horizontal rod in the other direction, e.g. . B. to the right is pushed. . lao

The contacts A ... E are actuated in order to carry out the connection with the desired line, as well as the normally closed contacts HB 1 ... HB 4 in order to separate the selector circuit of said selector from the associated common control circuit.

The test relays T and Dt in the memory return to the rest position. Relay Cs drops out as a result of the interruption of dt 4 and contact HBi in the line selector circuit, since relay Cs is kept in the following circuit: D wire, normally closed contact HBi, normally open contact fa 6, normally open contact hmi, normally open contact Ifshmax or Ifshmbi, earth.

Relay Cs caused by it 3 waste of relays OK. The memory control device is then completely in the rest position in a well-known manner; while the connection between the calling and the desired line is switched through in an also well known manner.

If a line is busy, the electrical identifier which identifies the vacancy of the said line is replaced by another which identifies the busy state. This is done in that the source Pd 4, which is connected to the resistor Rg associated with the line, is prevented from transmitting relatively positive pulses to the amplifier tube SVA 3, and by replacing these pulses with others from one of the sources Pd ι or Pd 2 are supplied, depending on whether the line is occupied locally or remotely. In this case, the source Pe ι is connected to the desired line via the connection set used in the existing connection at a point not shown, while the source Pd 2 is connected to the desired line via the D wire through the incoming connection circuit, which is used in the remote connection is used. A resistor Rhp with a rectifier Rcp 'in parallel is connected into the D wire of the line selector in series with this circuit as has been shown. If the source Pd4 is relatively positive (- 16 V), the wire coming from the resistor Rg is kept at -40 V because this wire is connected to the source Pd ι or Pd 2 via the D wire of the subscriber, which at that moment is -40 V, while the rectifier Rcp 'connected to the D wire of the line selector has a low resistance under these circumstances, so that the voltage difference between this wire (-40 V) and the source Pd 4 (■ - 16 V) is consumed in the resistor Rg. In this way, the pulses from source Pd 4 are no longer transmitted to the amplifier tube SVA? Instead of transmitting a pulse for the line in question in the time segment that corresponds to the period in which the source Pd4 is transmitting, a pulse is now sent in the time segment where one of the two sources Pd 1 or Pd 2 is positive, depending on whether it is source Pd ι or Pd 2 , which is connected to the D wire of the subscriber. If this source is positive (ie in the time segments 1 ... .120 for the source Pci 1 and in the time segments 121 ... 240 for the source Pd 2), then current flows from this source via the D wire of the Line selector circuit switched on resistor Rhp (the rectifier Rcp ' lying parallel to resistor Rhp is non-conductive under these circumstances) and from there to the D wire of the subscriber and the rectifiers ARCS, BRCS and CRCS in the common control circuit. If the valves belonging to the line let all three pass, which is the case in one of the 120 time periods that characterize the line in question, the potential of the D wire and therefore that of the grid of the amplifier tube is modified by the tube SVA $ then causes the transmission of a pulse via the regeneration circuit comprising the tubes SVAi and SVA 2.

It should be noted that although the D wire of the subscriber can now be at -16 V at a point in time when source Pd 4 is at -40 V, this source cannot influence the potential of the D wire because the rectifier Res in series with resistor Rg is non-conductive under these circumstances.

If the selected line is a busy single line, it is clear from the foregoing that no pulse is transmitted for this line in the time segment where Pd 4 is at -16 V, but that a pulse is transmitted when Pd 1 or Pd2 is present are at -16 V; If the line is locally occupied, the pulse is transmitted when Pd ι is at -16 V and if the line is remotely occupied, the pulse is transmitted when Pd 2 is at -16 V. The pulse is received in the memory in the period following that when the pulse was transmitted through the valve for the line in question, as the table in FIG. 22 shows. The circuit of the memory is such that the tube Vo 2 is influenced by a pulse in a time segment which is defined among the 100 possible time units, regardless of the larger periods 1 ... 120, 121 ... 240, 241. .. 360, 361 ... 480, where the said unit of time may occur. This time unit is determined in the memory exclusively by the combination of the tens and units of the desired subscriber number, as already indicated above.

Thus, when the line is occupied, the tube Vo 2 of the accumulator responds under the influence of a pulse produced by the said line during the period 1 ... 120; if the line is remote, the tube responds if it receives pulses during the period 121 ... 240. In both cases, the memory regenerates the said pulse by responding to the incoming pulse, and then passes it on via the C wire to the common control circuit using a method already described, thus causing the cold cathode tubes in the common control circuit to ignite has been declared; the said tubes are in fact controlled by sources which represent the periods 1 ... 120 in an entirely identical manner in each of the successive periods of 120 periods. The tube Vabu is controlled by a rectifier Rcbu connected to the pulse source Rd 1 in such a way that it can ignite in each of the 120 time segments of the first period; if the memory is on «5 a pulse in any period of the first

Period ι ... 120 responds, the tube Vabu ignites and thus keeps the location occupied state of the desired line ·. If a pulse arrives in any of the time segments 121 ... 240, then another tube, not shown, ignites, which is dependent on a rectifier connected to the source Rd 2 and records the fact that the desired line is remote. The response of the tube Vabu excites the corresponding anode relay Bu.

In addition to these tubes, another tube in the memory Via, which is not controlled by a rectifier, ignites in the same way as a call for a free line to report to the memory that the dialing process is over.

In accordance with the selection signals that the cathode tubes have received in the common control circuit, this circuit now reports the class of the desired line to the memory, just as in the case of a free line. Since we have assumed that the line in question is a single line, the relays Oa and Oe will energize. In the case where the desired line is a hunt group in a group of lines in non-numerical order, the resistor Rg is at one of the sources Pd ζ to Pd το, as indicated in the table “List of on-the-fly connection for the test criteria of lines” (FIG. 8); This source comes to --16 V in the corresponding period, so that a pulse is sent in one of the i-oo time units that characterize this line, and that during the period determined by the switched-on source Pd , provided that the line is free. If this is the case, the process is exactly the same as described for a free single line; if the memory responds to a pulse in one of the periods that corresponds to one of the sources Pd .. .Pd ίο, it causes it the ignition of a cold cathode tube in the memory to indicate that the choice is over, as well as the pulse received during the period corresponding to the source Pd 4, because during each of these periods the memory responds to a pulse occurring in a A period of time which characterizes a combination of tens and units and thus causes the tube Via to ignite during each of these periods, since this tube is not dependent on any pulse source via a rectifier. Furthermore, the cold cathode tubes of the common control circuit, in exactly the same. Respond in a manner during each period which corresponds to the sources Pd. Due to the fact that they are controlled by the sources which define a certain period of time only within a group of 120 time units.

The specific specification of the line class, such as it was given for S'ämmel connection lines has no influence on the process, since the Line as free 'has been found.

Samiriel connection lines of this type have their resistance Rg with one of the sources Pd 5 ...

Pd 10 connected, but are assigned exactly according to the method already described for a single line, so that the pulses supplied by the connected sources via Rg are suppressed and instead of their pulses from one of the sources Pd 1 or Pd 2 via the D wire of the desired Of the participant. So if a desired line of this type is seized, the process is initially exactly the same as with an occupied individual line, as already described, up to the point at which the line class information is received.

Regarding those lines that are not common Call number correspond to the group, the line class information is given as for a Single line, and therefore the call is handled in the same way as if a single line was seized; that part of the call that had already been set up collapses, and the caller receives busy signals while the common control circuit returns to the idle position.

For lines that correspond to the group's common calling number, the line class information is one of those in the table under "First line of the first hunt group number", "First line of the second hunt group number" and so on are listed; with others Words, a pulse is sent in one of the time units 78, 84, -96, 102, 108 or 114 accordingly the respective hunt group number.

When the memory receives this line class information, it is switched so that it is now after look for one of the other leaders in the group. This is done in the following way:

The response of relay Si causes in the memory the response of relay Ot via the normally closed contact or 1, normally closed contact it 5 and normally open contact si 4. Relay T is now connected to the Λ-Αά & ϊ , and via the contact HB 4 and Arbeitsskoutakt fa 5 in the line selector circuit causes relay LFSC in the ingenious control circuit to pick up. The check for double occupancy takes place and causes relay Dt and then relay Cs to respond. The switching of contacts ot 6 and dt 3 causes all line class relays Oa ... Oh to drop. no Relay Or picks up and breaks its contact Wi _{1 to} release relay Ot . The circuit, the tubes and relays that characterize the cable classes are also closed via the normally closed contact ot 6.

The control effect of the impulses arriving at the grids of the tubes Va 2, Va 3 and Va 4 is now modified. The grid of the tube Va 2 is connected to earth via the make contact ch, 2 and the make contact or 2. The grid of the tube Va 3 is connected to source Pa 1 via the break contact 0 * 4 and make contact si 3; and the grid of the tube Va4 is connected to earth via the normally open contact fs 4, normally closed contact phx, normally open contact or 3. Thus, no pulse coincidence can occur, except in the transmission periods that the source Fax

that are reserved for the line class signals.

As can be seen from the table in FIG. 8, the pulse identifying the first line of the first hunt group number leaves the relays Oc and. Address Ög . Since relay Bu is energized, relay Ph is excited via the normally open contact ogi, normally open contact oci and the normally open contact buz; a holding circuit is closed via the normally open contact ph2 and normally closed contact Im τ. The tightening of contact ph 5 causes the tube Via and relay Si to return to the rest position and causes the connection of relay Si with the tube Vib. Relay Bu releases its armature as a result of the interruption of contact ph 4.

The control effect exerted on the grids of the tubes Va2 ... Va 4 is again modified. The source Pd $ is connected to Va 2 via the make contact og6, make contact ph 3, make contact fs 6, make contact or 2 and make contact ch2. The sources Pa2 .. .Pa6 are each connected in parallel to the tube Va 3 via rectifiers via normally open contact ph6, normally open contact fs2, normally closed contact si 5 and normally closed contact 0 * 4. The tube Va 4 is connected to earth via the normally open contact fs4 and normally open contact phi.

The memory is now able to respond to the line identification pulses only in such time units that correspond to the operating periods of the sources Paz ... Pa6 and to respond to these said pulses only if they occur during the operating periods of the source Pd 5.
The need for two distinctions in hunt groups is now evident. The transmission of line identification pulses during the respective working periods of the sources Pd 5, Pd6 at the moment of the first test processes is irrelevant and has not been recorded. The transmission of the line class pulses by means of the sources Pa, Pb and Pc via one of the 20 line class cores in the common control circuit has indicated the desired hunt group. The accumulation of these pulses is used to control a further dialing process in the line selector for the lines of the desired hunt group, said lines having all of their identification pulses in the period Pd which corresponds to the hunt group. Thus, the number of the source Pd assigned to the hunt group is a criterion for the selection of a free line within the group, apart from the first. It is clear that during the dialing process within the hunt group the memory does not respond to impulses that may arrive from free individual lines or from occupied lines, since such impulses arrive during one of the periods which correspond to the time segments 361 ... 480 and ι ... 240 correspond; only the impulses coming from free lines of the desired hunt group, which emit their impulses in the period in which the memory can receive them, can act on this circuit, which is the case during the periods which correspond to the time segments 481 ... 600 for the first hunt group, 601 ... 720 for the second hunt group, and so on.

If a return pulse from the line selector arrives at the grid of Va 1, for example during the period Pd 5, a pulse from Vo 1 is generated and sent to the common control circuit in order to record the identity of the selected line. The generated pulse also causes the response of the tube Vib and relay Si.

It can be seen that when relay Ph has picked up and thus caused relay Si to drop out, the circuit of A-Aaex has been interrupted at ph8 and oti and that therefore relay LFSC of the common control circuit of the line selector has dropped out.

The drop of relay LFSC in the common control circuit then causes relay LFSD or LFSE to drop, which in turn drops the vertical magnet LFVM so that the vertical rod that has been raised returns to the rest position.

Relay LFSB in the common control circuit can now be excited again via the normally closed contact Ifse 3, normally closed contact Ifsh 1, normally open contact fa 1, normally closed contact HBt, and earth. Battery is connected to tube SVA via the normally open contact Ifsb4, the circuit then again enters the state where the storage pulses are transmitted through valves and the gain and regeneration steps for each of the lines.

In the case under consideration, the memory responds to the pulse transmitted by the common control circuit at any point in time in the period corresponding to the desired hunt group group , ie to the pulses coming from all free lines whose resistance Rg corresponds to the desired group a certain one of the sources Pd 5 ff. is connected, so that said memory is then able to send a pulse in the period when said source is positive.

If the memory responds, it works at the moment when such a line generates a pulse sends, just as described for a call to a free individual line, to their freedom and the subsequent operations are to complete the connection exactly the same as already described.

It should be mentioned here that the line Ulassen details for the lines of a hunt group of the type in question, from the first apart from that of a single line, d. H. it is identified by period no. 6 draws. iao

A small hunt group with lines in direct succession leaves Assemble yourself by using flying leads for all lines except the the last, a line class specification, with the line class wire connected to COL wire no. 12

will; these lines then send a pulse in time segment no. J2 as line class information, while the last line in the group is connected like a single line, ie connected to wire no.

The resistances of all lines of this type of hunt group must be connected to source Pd 4 as if they were individual lines.

If a call is to be connected to any free line in the group, - the call is carried out exactly as specified for a free individual line, since the line class information is based on the switching through of such a line Connection then has no influence. If you have any assigned leadership of the group calls, apart from the last one, the memory receives the information that said line is busy exactly as already described, whereby the line class information is reported in the usual way, ao Since this message is - of a kind, its a small one Hunt group indicates and thus announces, that the next line in numerical order is to be checked, the memory switches on receipt of this signal including the common Control circuit in the dial position as for the type of Sanimel connection groups with numerical not in direct; Row lying lines described, but with the difference that the Memory is now switched so that it can respond to the pulses that the line with a correspond to the number following the line dialed first, so this is now next line selected as already described for a single line. When she is free is it occupied in the normal way; if it is busy and it is not the last line of the Group.acts, the process of dialing the numerically closest line is repeated, and this process continues until either a free line or the last line in the group is found .. This last line is characterized by the fact that the line class specification is that of a single line, so that it is in use Single line is dealt with, if it is also occupied .:

To simplify the 'memory circuits, the individual lines of a hunt group of this type have call numbers that differ only in the tens digit, so that there are in the event that the selection of the next line becomes necessary, it is only necessary that the Change one place corresponding marking.

The processes that go on in memory for this type of hunt group are now stored in the individually described:

When the information indicating the state of the selected line is received, relay Bu as well as relay Si is energized, as already described. Relay Ot picks up like the test relays T and Dt. The interruption of the contacts ot 6 and dt 3 causes the previously activated line class relays to drop out. Relay Or is excited and causes relay 'Ot to drop.

Contacts or 2 and or 3 connect the grids of tubes Va 2 and Va 4 to earth, and contact si 3 connects the grid of tube Va 3 to source Pa i so that the memory is able to receive line class information as before . The sources Paz .., Pa6 are separated at sis.

The line class relays that are energized when it is a hunt group of the type where the lines are in numerical order are Oc and Of (see in this context under "Number of the second line" in the table in Fig. 8) . Relay Ph is excited in the following circuit: make contact of 5, make contact oc 1, make contact bu2. A holding circuit is then closed via the normally open contact ph 2 and normally closed contact Im i.

In the present case relay Ia is also excited via the working contact Eis of a relay Ei, which picks up as soon as the last position in the memory has been recorded, the working contacts oc 6, of 6, es 2 and earth. Relay Im is delayed, is parallel to relay Ia and only responds shortly after said relay Ia .

Relay Ia causes the device that picked up the ones digit to advance one step. If, for example, a single movement selector of a well-known type with eleven positions go is used in the memory, then relay Ia closes an incremental circuit for the memory selector when responding, said memory advancing by one step in a well-known manner. The conversion of the recorded number, which is done by well-known cross-wiring methods, is thus modified, and the source Pa _1, which was previously connected to normally closed contact ph6, is disconnected and replaced by the next source. The interruption of contact ph4 caused relay Bu to drop out, and the interruption of contacts bu2 and Im 1 caused relay Ph to drop out.

The simultaneous interruption of the contacts oii and ph8 caused the relays T and Dt in the memory and the relay LFSC in the common control circuit to drop out ». Relay LFSB in the common control circuit is again excited and applies battery to the cathode of tube SVA3. Return pulses are then transmitted to the memory; In the latter, the grids of the tubes Va2, VaZ and Va 4 are in turn connected to the source Pc via the work contact ch2, break contact or 2 , make contact fs 6, break contact ph.3 or with source Pa via the break contact ot 4, break contact si 5 , Normally open contact fs 2, normally closed contact ph 6 or with source Pb via normally open contact fs 4, normally closed contact ph τ, normally closed contact or 3. When the pulse is received from the next line, the same processes take place in the memory as before, and the other lines of the hunt group are checked in the manner indicated above up to the last one, if necessary, which provides information corresponding to a single line so that, if it is also occupied, the memory returns to the idle position and the connection is released.

The transmission of the line class signal for an ordinary subscriber line has already been described been.

If the desired subscriber has limited switching authorization, the line class relays that have picked up are not Oa and Oe, but Oa and Of, but the circuits provided for connecting the connection are set up so that they can work in the same way whether it is now relays Oa and Oe or relays Oa and Of are energized. In fact, such participants are only authorized to a limited extent for outgoing calls; In the case of incoming calls, on the other hand, there is no difference between calls for ordinary and those for subscribers with limited switching authorization.

If the selected subscriber is absent for a long time and precautions have been taken to ensure that incoming calls are picked up by an officer, the transmitted line class signal causes the relays Oa and Og to respond. Relay Lp is then excited via the normally open contact fs 7, normally open contact ogj and normally open contact οαβ. Closing contact Ip 2 causes relay So to pick up, which interrupts its contact so 2 and causes relay Fg to drop out. The interruption of contact fg2 causes relay Fs to drop out. The interruption of contact so 4 removes the earth connection from wire CAL, so that relay CCDA in the circuit temporarily drops out (Fig. 10). The interruption of contact ceda 5 (Fig. 9) causes the group selector to return to the idle state; the line selector also drops out because wires A, B, C, D and E are temporarily disconnected from the memory.

The interruption of contact so 5 releases relay Rc , which had been energized when relay La itself had picked up as a result of the normally open contact IhJ . Relay Rc drops slowly and in turn closes a ground connection for wire CAL via its contact rc 5, which ends in the connection set, in such a way that relay CCDA is again energized. The interruption of contact so 2 causes relay Fg to drop out, in that a working circuit for said relay is again prepared by the normally closed contact rc 3. The interruption of contact fg2 causes relay Fs to drop out. The grid of the tube Va 2 is now via the normally closed contact fs 6, normally closed contact fgS, normally open contact

So se 3 and the break contact rc 4 connected to the source Pd 10, which is used> to initiate a connection with an officer via a first group selector.

If the desired line is one whose subscriber has received a different number, the line class relays Oa and Oh are excited, and relay Cn is excited via the make contact foi, make contact 0/14, make contact oaj; this relay is maintained via the normally open contact cn 1 and the normally open contact lh 12. Closing contact c% 2 triggers the response of relay So, which in turn interrupts its contact so 2 to cause relay Fg to drop out, and its contact so 4 to remove the earth from the CAL wire which ends in the connection set. As in the case of absent participants already described, the connection already established is released and a connection is established with an officer, depending on the source Pd 10, which is connected to the grid of the tube Va 2 via the normally open contact J03, normally closed contact fg3 .

The operations that take place in the case of a hunt group where the lines are in numerical order Consequences may or may not be, have already been described.

If we look at the functioning of the system as a whole, it can be seen that the memory controller is entirely passive; in other words, it never does anything of its own accord, it does always waits for instruction, whereupon it switches over accordingly to correspond to the received Instructions to initiate other operations.

It's not new to a storage controller instructions that enable him to modify his way of working for specific purposes; but the fact that a memory controller is available that is on command for each operation waits and is not arranged in such a way that there is a whole sequence of predetermined processes is new.

Claims (9)

PATENT CLAIMS: 1. Circuit arrangement for the production of connections in automatic telecommunications systems, in which the identification of a calling line from a larger number of lines with the help of static switching means and using control pulses of different times, according to additional patent 853 302, characterized in that the individual elective levels. (For example AS, GW, LW) memory control devices (Fig. 12, 13, 14, 15) are assigned, the switching elements of which respond to control signals of each selection stage and, depending on the signals received, enable the subsequent selection or change it into another switching process. 2. Circuit arrangement according to claim 1, characterized in that from each selection stage (AS, GW, LW) control signals are given to a memory control device which characterize the connection or line class. 3. Circuit arrangement according to claim 2, characterized in that the control signals from There are consecutive pulses and a group with a common Form a time factor that differs from that of the dialing signal group. 4. Circuit arrangement according to claim 1 to 3, characterized in that the memory control device also picks up voter signals and is set by them. 5. Circuit arrangement according to claim 1 up to 4, characterized in that each voter (e.g. call seeker, group dialer, line selector) a number of common control or class signal lines as well as each port or each subscriber line is assigned its own control or class signal line and that connections between one or more subscriber lines and the common lines for determining a class or control signal are provided. 6. Circuit arrangement according to claim 5, characterized characterized in that the selection and class signals are based on a multiple voter (e.g. based on cross-rod basis) assigned control circuit are transmitted. 7. Circuit arrangement according to claim 5 and 6, characterized in that the control or Class signals through a common control circuit over several stages of electrical Valves that are between the connection or subscriber lines and a common Line wires are arranged, with each valve stage temporally spaced pulses are assigned to which control or class signal lines are applied. 8. Circuit arrangement according to claim 6, characterized in that each storage device a single voter from a multiple voter from a group is assigned to establish a connection with a group of verbitiidation sentences (2nd B. between a call finder and a group or line dialer). 9. Circuit arrangement according to claim 8, characterized in that each call detection circuit a group is assigned a single dialer of a multiple dialer to which the connection is established with a group of connection sets or memories. In addition 8 sheets of drawings β «7462.53